Metabolic engineering of lipid metabolism by improving fatty acid binding and transport

ABSTRACT

CHI like fatty acid binding proteins and genes, recombinant cells and organisms, methods of metabolic pathway engineering to improve lipid production in cells, Crystal structures of CHI like fatty acid binding proteins, methods of engineering CHI like fatty acid binding proteins and systems thereof are provided.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims priority to and full benefit of U.S. Ser. No. 60/831,046 filed Jul. 13, 2006, METABOLIC ENGINEERING OF LIPID METABOLISM BY IMPROVING FATTY ACID BINDING AND TRANSPORT by Pojer et al., the full disclosure of which is incorporated herein by reference in its entirety.

STATEMENT AS TO RIGHTS TO INVENTIONS MADE UNDER FEDERALLY SPONSORED RESEARCH AND DEVELOPMENT

The application was supported in part by National Science Foundation MCB-0236027. The government may have certain rights in the invention.

FIELD OF THE INVENTION

This invention is in the field of metabolic pathway engineering of lipids in plants and in the field of protein crystallography and design.

BACKGROUND

Currently, the majority of vegetable oil production (estimated at 87 million metric tons with approximate market value of 40 billion U.S. dollars) goes into human consumption, with as much as 25% of human caloric intake in developed countries being derived from plant fatty acids. In addition to their importance in human nutrition, plant fatty acids are also major ingredients of nonfood products such as soaps, detergents, lubricants, biofuels, cosmetics, and paints. With the accelerating costs of petroleum, vegetable oils provide an increasingly cost-effective alternate source for raw materials.

Selecting plants for increased (and decreased) oil production by classical genetic selection methods has been ongoing for at least a century. Indeed, the complexity in determining trait-genotype associations for the seemingly simple trait of oil production has been demonstrated. For example, Laurie et al. (2004) “The Genetic Architecture of Response to Long-Term Artificial Selection for Oil Concentration in the Maize Kernel” Genetics 168:2141-2155 describe an association study that involved selection of the maize kernel for the simple phenotype of altered oil concentration, over a period of more than a century (one of the longest running selection experiments in biology). The association study detected about 50 “quantitative trait loci” (QTL) that contributed to changes in oil concentration over the 100+ year period, together accounting for only about 50% of the observed variance (suggesting that even more than the 50 identified QTL influence the oil concentration phenotype). The individual QTL effect estimates for the identified QTL were small and largely additive. In the oil phenotype experiment described by Laurie et al., the populations changed from a 4.7% oil content at the beginning of the experiment to a 19.3% oil content at the end, among the lines selected for high oil content, and a 1.1% oil content in the lines selected for low oil content.

The biochemical study of de novo fatty acid biosynthesis in plants is, thus, fundamentally important and practically essential for the metabolic engineering of fatty acid biosynthesis in agronomically important crops (see also, Thelen and Ohlrogge (2002) “Metabolic engineering of fatty acid biosynthesis in Plants,” Metabolic Engineering 4: 12-21; Broun et al. (1999) “Genetic engineering of plant lipids,” Annu. Rev. Nutr. 19: 197-216). In plants, the majority of fatty acids are biosynthesized in the plastid. Over the last two decades nearly all aspects of fatty acid metabolism in plants have been uncovered. However, one of the remaining questions that has thus far resisted elucidation is how free fatty acids are transferred from an inner thylakoid membrane to an outer envelope of a plastid, where they are reactivated to acyl-CoAs for utilization in cytosolic glycerolipid synthesis. Without knowledge of how this mechanism works, efforts to increase flux through fatty acid synthesis pathways by metabolic engineering have been hampered.

The present invention overcomes these previous difficulties, by providing a new family of chalcone-isomerase like genes that encode fatty acid binding proteins that, e.g., assist in transport of fatty acids from the thylakoid membrane to the outer plastid envelope. These and other features of the invention will be apparent upon review of the following.

SUMMARY OF THE INVENTION

The present invention provides the discovery that chalcone isomerase like fatty acid binding proteins are likely fatty acid transporters that facilitate transport of fatty acids from the thylakoid membrane to the outer plastid envelope. This discovery provides a target for engineering lipid metabolism, e.g., in plants. For example, lipid production is likely to be increased by overexpressing chalcone isomerase like fatty acid binding proteins in cells of the plants. In addition, the complete crystal structures of two of these proteins are provided. This crystal structure information makes it possible to engineer the proteins to modulate fatty acid binding and plastid transport, e.g., to increase transport activity.

Accordingly, in a first aspect, the invention provides a recombinant cell that expresses a heterologous chalcone isomerase like fatty acid binding protein gene, which encodes a chalcone isomerase like fatty acid binding protein that binds to a fatty acid in the cell.

A variety of examples of such genes and proteins are provided, including At287 (At1g53520), At279 (At3g63170), At396 (At2g26310) or homologs thereof, e.g., those identified in Example 2. Homologs include chalcone isomerase like fatty acid binding proteins that are at least 25% identical to At287, At279, or At396 and that encodes a conserved Arg amino acid residue in a position corresponding to Arg 103 of At279 or Arg 114 of At287, and that encodes a conserved Tyr residue in a position corresponding to Tyr 116 of At279 or Tyr 126 of At287, which conserved Arg and conserved Tyr residues participate in sequestering a carboxylic acid moiety on the fatty acid when the fatty acid is bound to the protein. Homologs with higher levels of identity are also a feature of the invention, including genes that are at least 60% identical to At287, At279, or At396.

Optionally, the gene is highly expressed, e.g., more highly expressed than a corresponding native chalcone isomerase like fatty acid binding protein gene of the cell. This high level of expression increases lipid content of the recombinant cell as compared to a corresponding cell that does not express the gene. That is, the protein may regulate transport of the fatty acid from an inner thylakoid membrane of the cell to an outer membrane of a plastid of the cell, and over expression of the protein may increase plastid transport.

The cell is optionally a plant cell and can be part of a recombinant plant. Examples of suitable plants that can be made recombinant include plants that are members of a family selected from: Graminae, Leguminosae, Compositae and Rosaciae, or wherein the plant is a member of a genus selected from Agrostis, Allium, Antirrhinum, Apium, Arachis, Asparagus, Atropa, Avena, Bambusa, Brassica, Bromus, Browaalia, Camellia, Cannabis, Capsicum, Cicer, Chenopodium, Chichorium, Citrus, Coffea, Coix, Cucumis, Curcubita, Cynodon, Dactylis, Datura, Daucus, Digitalis, Dioscorea, Elaeis, Eleusine, Festuca, Fragaria, Geranium, Glycine, Helianthus, Heterocallis, Hevea, Hordeum, Hyoscyamus, Ipomoea, Lactuca, Lens, Lilium, Linum, Lolium, Lotus, Lycopersicon, Majorana, Malus, Mangifera, Manihot, Medicago, Nemesia, Nicotiana, Onobrychis, Oryza, Panicum, Pelargonium, Pennisetum, Petunia, Pisum, Phaseolus, Phleum, Poa, Prunus, Ranunculus, Raphanus, Ribes, Ricinus, Rubus, Saccharum, Salpiglossis, Secale, Senecio, Setaria, Sinapis, Solanum, Sorghum, Stenotaphrum, Theobroma, Trifolium, Trigonella, Triticum, Vicia, Vigna, Vitis, Zea, the Olyreae, and the Pharoideae. For example, the plant can be a Zea mays, soybean, cotton, Brassica naupus, Brassica juncea, tobacco, sunflower, safflower, rapeseed, canola, olive or Arabidopsis thalina plant.

The CHI like fatty acid binding protein can bind any of a variety of fatty acids, including oleic acid, lauric acid, myristic acid, palmitic acid and/or steric acid. The fatty acid can be saturated or unsaturated.

In a related aspect, the invention includes a recombinant cell that expresses a heterologous regulator of a chalcone isomerase like fatty acid binding protein gene. Such regulators include transcription factors that regulate expression of the gene, anti-sense nucleic acids that inhibit transcription or translation of an mRNA encoded by the gene, siRNAs that inhibits translation of an mRNA encoded by the gene, and miRNAs that inhibit translation of an mRNA encoded by the gene. The regulator can increase or decrease production of a chalcone isomerase like fatty acid binding protein in the cell, thereby increasing or decreasing lipid content of the cell. All of the above features apply to this embodiment as well, e.g., with respect to cells, plants, fatty acids, etc.

In another related aspect, an expression vector that encodes a chalcone isomerase like fatty acid binding protein is provided. All of the above features apply to this embodiment as well, e.g., the vector can encode the genes noted above, and can include an expression cassette expressible in a plant such as any of those noted above. A cassette of the vector is desirably configured for overexpression of the chalcone isomerase like fatty acid binding protein in a target cell (e.g., in a plant), e.g., to increase lipid production in the cell.

An isolated chalcone isomerase like fatty acid binding protein is also a feature of the invention. The isolated protein can be any of those noted above, e.g., At287, At279, At396 or a homolog thereof. A crystal comprising such protein is also a feature of the invention. The isolated protein or crystal optionally includes a ligand bound to the protein e.g., a fatty acid bound to the protein.

The invention also provides related methods. For example, the invention provides a method of making a recombinant cell. The method includes introducing a recombinant gene into a cell, which recombinant gene encodes a recombinant chalcone isomerase like fatty acid binding protein. Typically, the recombinant gene is expressed in the resulting recombinant cell. Any of the features noted above for the compositions apply to the methods as well, e.g., the genes, cells or plants can include any of those noted above, etc. The recombinant chalcone isomerase like fatty acid binding protein is optionally more highly expressed than a native chalcone isomerase like fatty acid binding protein homolog and expression of the recombinant chalcone isomerase like fatty acid binding protein optionally increases lipid content of the cell. A recombinant plant cell made by the method is also a feature of the invention.

In a related aspect, the invention provides a method of modulating lipid content of a cell. The method includes: expressing a recombinant chalcone isomerase like fatty acid protein gene in the cell, or expressing a heterologous modulator of a chalcone isomerase like fatty acid protein gene in the cell. Expression of the recombinant gene or heterologous modulator modulates lipid content of the cell. Any of the features noted above with respect to the methods or compositions apply equally here. For example, expression of the recombinant chalcone isomerase like fatty acid protein gene optionally increases lipid content of the cell. Expression of the modulator increases or decreases lipid content of the cell, depending on the intended application. A cell made by the method is also a feature of the invention.

The invention also provides for maker assisted selection to select plants for a lipid content phenotype. For example, a method of selecting a plant for lipid content is provided. The methods include identifying a polymorphism in a plant population that correlates with a phenotype encoded by a chalcone isomerase like fatty acid binding protein gene; and, performing marker assisted selection of the population to select a plant in the population for the polymorphism. Any of the various features noted above are applicable here as well. For example, the gene can be the same as or homologous to a gene that encodes At287, At279, or At396. A plant produced by the method is also a feature of the methods.

Similarly, transgenic plants in which the CHI like fatty acid binding protein genes are knocked down or knocked out, as well as upregulated and/or over-expressed are a feature of the invention. Such plants (e.g., Arabidopsis, tomato, tobacco, etc.) can be examined throughout their growth cycle for fatty acid and lipid/oil content in various tissues and seeds.

In another aspect, the invention provides a method of modifying a chalcone isomerase like fatty acid binding protein. The method includes accessing an information set derived from a crystal structure of the protein or homolog thereof, and, based on information in the information set, predicting whether making a change to the structure of the protein will increase or decrease binding to a fatty acid binding protein ligand. The protein is modified based upon on the prediction. The information set optionally includes crystal structure information as provided in the figures herein.

A system comprising an information storage module comprising an information set derived from a crystal structure of a chalcone isomerase like fatty acid binding protein is also a feature of the invention. For example, a computer comprising a database of such information is a feature of the invention.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 is a clustalw alignment of CHI family members. At279 (At3g63170) and At287 (At1g53520) are shown on lines 5 and 4, respectively. At396 (at2g26310), the closest relative to At279 in the figure, is shown on line 6. The two conserved amino acids for sequestration of carboxylic acid moieties through hydrogen bonding with lauric acid are boxed. The catalytic authentic chalcone isomerase, AtCHI (at3g55120), as well as two close relatives, At233 (At5g6620) and At209 (At5g05270) are shown on lines 1, 2, and 3, respectively.

FIG. 2A is a table that includes a drawing of chalcone isomerase like proteins. FIG. 2B shows an expansion of AT279 bound to Lauric acid.

FIG. 3 is an LC-MS analysis of fatty acids bound to AT279 and At287. FAs were extracted from purified E. coli over-expressing At279 and At287. Extracted ion chromatograms (EIC) of negative mode mass spectrometer chromatograms (-All MS) of lauric acid (C:12:0) (m/z)=198.7 ([M-H]−), myristic acid (C14:0) (m/z)=226.9 ([M-H]−), palmitic acid (C16:0) (m/z)=254.9 ([M-H]−) and steric acid (C18:0) (m/z)=282.9 ([M-H]−), presented compared to standards.

FIG. 4 is set of crystal structure coordinates for chalcone isomerase.

FIG. 5 is a set of crystal structure coordinates for AT279.

FIG. 6 is a set of crystal structure coordinates for AT287.

DETAILED DESCRIPTION

The current invention describes a sub-family of chalcone isomerase like genes, the protein products of which bind fatty acids (FA) with high affinity. Binding was established first by the elucidation of the high resolution crystal structure of one protein expressed and purified from E. coli (At3g63170) and confirmed by HPLC-MS-MS analyses of extractions of protein samples of At3g63170 and a close relative (At1g53520). The proteins that retain the same three dimensional fold of chalcone isomerase but lack key catalytic residues are widely distributed in plants, various bacteria, fungi and possibly other eukaryotic organisms. Bioinformatic analysis of the two genes in question strongly suggest that the nuclear encoded proteins are localized in the chloroplast, where the majority of plant fatty acid biosynthesis occurs. Moreover, it is likely that these two proteins are directly involved in the transport of free fatty acids from the inner thylakoid membrane to the outer envelope of the plastid where they are reactivated to acyl-CoAs for utilization in cytosolic glycerolipid synthesis.

Metabolic engineering of plant fatty acid biosynthesis (FAS) has progressed rapidly in the past 10 years and has led to the commercialization of several modified oilseed crops. However, it has been difficult to engineer plants with increased flux through the biosynthetic pathways (Thelen and Ohlrogge (2002) “Metabolic engineering of fatty acid biosynthesis in Plants,” Metabolic Engineering 4: 12-21; Broun et al. (1999) “Genetic engineering of plant lipids,” Annu. Rev. Nutr. 19: 197-216). Our discovery of a new FA binding protein family and their over-expression in FA bio-engineered plants can modulate/improve plant FA content by allowing natural FA to be transported more efficiently. The search for these transporters has been intense but was previously unresolved (Koo et al. (2004) “On the Export of Fatty Acids from the Chloroplast” J. Biol. Chem. 279(16): 16101-16110). Moreover, our knowledge of the detailed binding mode of natural FAs, as well as synthetic FAs, provide the necessary tools for structure-based engineering of modified FA transporters.

We discovered two naturally-occurring FA binding proteins using bioinformatic analysis of available genomic sequencing data from the plant Arabidopsis thaliana. These two homologs, referred to as AtCHi279 (At3g63170) and AtCHI287 (At1g53520) based upon their amino acid length are small proteins located on different chromosomes. Sequence information can be found for At3g63170 and At1g53520, e.g., in the public UniProt database (on the world wide web at pir(dot)uniprot(dot)org), associated with accession numbers Q9M1X2 and Q9C8L2, respectively. Note that the At3g63170 and At1g53520 designations are accession numbers in the publicly available “The Arabidopsis Information Resource” (TAIR) database, found on the world wide web at arabidopsis(dot)org (which can also be linked to from the relevant accession numbers in UniProt and vice-versa). In plants, these proteins are ubiquitous and often abundantly expressed. The last 200 C-terminal amino acids share homology to our previously solved chalcone isomerase (CHI) crystal structure; however, they lack key residues previously identified in our laboratory that are critically involved in the near diffusion controlled (“Perfect Enzyme”) and stereospecific conversion of chalcone into (2S)-naringenin (Jez and Noel (2001) “Reaction mechanism of Chalcone Isomerase” J. Biol. Chem. 277(2): 1361-1369.). Within the first 80-90 N-terminal amino acid residues, a plastid signal sequence is found. AtCHI279 was annotated as localized in the plastid stroma by the plastid proteome database, as we would expect.

We solved the x-ray crystal structure of AtCHI279, and have collected high quality x-ray data for AtCHI287. Crystal coordinates are provided in FIGS. 5-6; coordinates for chalcone isomerase are also provided for comparison in FIG. 4; crystal structure coordinates for various chalcone isomerases are available on-line, e.g., through portals to the protein data bank such as RCSB (on the world-wide web at rcsb(dot)org/pdb/home/home(dot)do), the interpro website (on the world wide web at ebi(dot)ac(dot)uk/interpro/) and the EMBL-EBI website (on the world wide web at ebi(dot)ac(dot)uk/). The structure of AtCHI279 recently completed confirms conservation of the unique open-faced β-sandwich fold of CHI but a highly divergent active site cavity as suggested by sequence alignments. As we elucidated the structure, a small molecule, the fatty acid lauric acid likely derived from E. coli, was sequestered in a well-organized binding pocket in AtCHI279 that only partially overlaps with the previously characterized catalytic pocket of CHI. The carboxylic acid group is nicely sequestered by electrostatic interactions with absolutely conserved Arg and Tyr residues while the fatty acyl chain is bound in a new hydrophobic cavity formed in the CHI fold. Further, LC-MS-MS analysis of recombinantly prepared AtCHI279 and AtCHI287 confirmed that they bind an entire set of linear fatty acids representative of E. coli's fatty acid complement (C12 to C18 saturated, and monounsaturated). Identical analyses of the two most derived CHIs clearly possessing authentic CHI activity showed no such fatty acid binding activity.

Together, these observations indicate that this CHI like fatty acid binding protein family can be used to improve the engineering of lipids in plants. Indeed, Homologs of these FA binding proteins are also found outside higher plants, for example in unicellular algae Chlamydomonas, as well as in eukaryotic slime mold Dictyostelium, suggesting an important role of this family of proteins in lipid metabolism beyond plants.

DEFINITIONS

Before describing the present invention in detail, it is to be understood that this invention is not limited to particular devices or biological systems, which can, of course, vary. It is also to be understood that the terminology used herein is for the purpose of describing particular embodiments only, and is not intended to be limiting. As used in this specification and the appended claims, the singular forms “a”, “an” and “the” include plural referents unless the content clearly dictates otherwise. Thus, for example, reference to “a plant” includes a combination of two or more plants; reference to a “cell” optionally includes mixtures/cultures of cells, and the like.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the invention pertains. Although any methods and materials similar or equivalent to those described herein can be used in the practice for testing of the present invention, the preferred materials and methods are described herein. In describing and claiming the present invention, the following terminology will be used in accordance with the definitions set out below.

A Chalcone isomerase like fatty acid binding protein: is a protein that shares detectable homology with a chalcone isomerase or with At287, At279 or At396, wherein the protein binds one or more fatty acid. Typically, the chalcone isomerase like fatty acid binding protein does not comprise chalcone isomerase activity.

Expression vector: as used herein refers to a vector comprising operably linked polynucleotide sequences that facilitate expression of a coding sequence in a particular host organism (e.g., a bacterial expression vector or a plant expression vector). Polynucleotide sequences that facilitate expression in prokaryotes can include, e.g., a promoter, an enhancer, an operator, and a ribosome binding site, often along with other sequences. Eukaryotic cells can use promoters, enhancers, termination and polyadenylation signals and other sequences that are generally different from those used by prokaryotes.

A Genetic element or “gene” refers to a heritable sequence of nucleic acid (typically DNA), i.e., a genomic sequence, with functional significance. Genes typically include an expressible nucleic acid sequence.

A Genotype is the genetic constitution of an individual (or group of individuals) at one or more genetic loci, as contrasted with the observable trait (the phenotype). Genotype is defined by the allele(s) of one or more known loci that the individual has inherited from its parents. The term genotype can be used to refer to an individual's genetic constitution at a single locus, at multiple loci, or, more generally, the term genotype can be used to refer to an individual's genetic make-up for all the genes in its genome. A “haplotype” is the genotype of an individual at a plurality of genetic loci. Typically, the genetic loci described by a haplotype are physically and genetically linked, i.e., on the same chromosome segment. The terms “phenotype,” or “phenotypic trait” or “trait” refers to one or more trait of an organism. The phenotype can be observable to the naked eye, or by any other means of evaluation known in the art, e.g., microscopy, biochemical analysis, etc. In some cases, a phenotype is directly controlled by a single gene or genetic locus, i.e., a “single gene trait.” The CHI like fatty acid binding protein genes herein can comprise single gene traits. In other cases, a phenotype (such as overall lipid production of a cell or plant) is the result of several interacting genes. A “quantitative trait loci” (QTL) is a genetic domain that is polymorphic and affects a phenotype that can be described in quantitative terms, e.g., lipid content, and, therefore, can be assigned a “phenotypic value” which corresponds to a quantitative value for the phenotypic trait. A QTL can act through a single gene mechanism or by a polygenic mechanism.

Germplasm: refers to genetic material of or from an individual (e.g., a plant), a group of individuals (e.g., a plant line, variety or family), or a clone derived from a line, variety, species, or culture. The germplasm can be part of an organism or cell, or can be separate from the organism or cell. In general, germplasm provides genetic material with a specific molecular makeup that provides a physical foundation for some or all of the hereditary qualities of an organism or cell culture. As used herein, germplasm includes, e.g., cells, seed or tissues from which new plants may be grown, or plant parts, such as leafs, stems, pollen, or cells, that can be cultured into a whole plant.

A Heterologous component of a cell is a component that is derived from a source other than the cell, or that appears in the cell in a non-natural (artificial) context.

Homologous: Proteins and/or protein sequences are “homologous” when they are derived, naturally or artificially, from a common ancestral protein or protein sequence. Similarly, nucleic acids and/or nucleic acid sequences are homologous when they are derived, naturally or artificially, from a common ancestral nucleic acid or nucleic acid sequence. For example, any naturally occurring CHI like fatty acid binding protein can be modified by any available mutagenesis method to produce a mutant CHI like fatty acid binding protein. Homology is generally inferred from sequence identity or similarity between two or more nucleic acids or proteins (or sequences thereof). The precise percentage of identity or similarity between sequences that is useful in establishing homology varies with the nucleic acid and protein at issue, but as little as 25% sequence similarity between proteins (and less between nucleic acids, due to the degeneracy of the genetic code) is routinely used to establish homology. Higher levels of sequence similarity, e.g., 30%, 40%, 50%, 60%, 70%, 80%, 90%, 95% or 99% or more can also be used to establish homology. Methods for determining sequence similarity percentages (e.g., BLASTP and BLASTN using default parameters) are described herein and are generally available.

Plant: a plant can be a whole plant, any part thereof, or a cell or tissue culture derived from a plant. Thus, the term “plant” can refer to any of: whole plants, plant components or organs (e.g., leaves, stems, roots, etc.), plant tissues, seeds, plant cells, and/or progeny of the same. A plant cell is a cell of a plant, whether part of the plant, or taken from a plant, or derived through culture from a cell taken from a plant. Thus, the term “plant” includes whole plants, plant cells, plant protoplast, plant or tissue culture from which plants can be regenerated, plant calli, plant clumps and plant cells that are intact in plants or parts of plants, such as seeds, pods, flowers, cotyledons, leaves, stems, buds, roots, root tips and the like.

A Recombinant cell: is a cell that is made by artificial recombinant methods. The cell comprises one or more transgenes, e.g., heterologous CHI like fatty acid binding protein genes, introduced into the cell by artificial recombinant methods.

Transgenic plant: refers to a plant that comprises within its cells a heterologous polynucleotide. In many embodiments, the heterologous polynucleotide is stably integrated within the genome such that the polynucleotide is passed on to successive generations. The heterologous polynucleotide may be integrated into the genome alone or as part of a recombinant expression cassette. “Transgenic” is used herein to refer to any cell, cell line, callus, tissue, plant part or plant, the genotype of which has been altered by the presence of heterologous nucleic acid including those transgenic organisms or cells initially so altered, as well as those created by crosses or asexual propagation from the initial transgenic organism or cell. The term “transgenic” as used herein does not encompass the alteration of the genome (chromosomal or extra-chromosomal) by conventional plant breeding methods (e.g., crosses) or by naturally occurring events such as random cross-fertilization, non-recombinant viral infection, non-recombinant bacterial transformation, non-recombinant transposition, or spontaneous mutation.

A specified nucleic acid is derived from a given nucleic acid when it is constructed using the given nucleic acid's sequence, or when the specified nucleic acid is constructed using the given nucleic acid. For example, a cDNA or EST is derived from an expressed mRNA.

Chalcone Isomerase Like Fatty Acid Binding Proteins and Genes

CHI like fatty acid binding protein genes are expressed, e.g., to increase flux through fatty acid synthesis pathways. For example, elevated expression of CHI like fatty acid binding proteins may lead to increased transport of lipids such as C12 to C18 saturated, or monounsaturated lipids, including oleic acid, lauric acid, myristic acid, palmitic acid, steric acid, etc., from an inner thalakoid membrane to the outer surface of a plant plastid. This increases the rate at which such lipids are reactivated to acyl-CoAs for utilization in cytosolic glycerolipid synthesis.

CHI like fatty acid binding proteins are those fatty acid-binding proteins that share detectable homology to At287, At279, At396 and/or to a chalcone isomerase (including At287, At279 and At396). Nucleic acids are homologous when they derive from a common ancestral nucleic acid, e.g., through natural evolution, or through artificial methods (mutation, gene synthesis, recombination, etc.). Homology between two or more proteins is usually inferred by consideration of sequence similarity of the proteins. Typically, protein sequences with as little as 25% identity, when aligned for maximum correspondence, are easily identified as being homologous. In addition, many amino acid substitutions are “conservative” having little effect on protein function. Thus, sequence alignment algorithms typically account for whether differences in sequence are conservative or non-conservative.

Thus, homology can be inferred by performing a sequence alignment, e.g., using BLASTN (for coding nucleic acids) or BLASTP (for polypeptides), e.g., with the programs set to default parameters. For example, in one embodiment, the protein is at least about 25%, at least about 50%, at least about 75%, at least about 80%, at least about 90% or at least about 95% identical to At287, At279, and/or At396. Available examples of such homolgous proteins include those identified in Example 2.

Homologous CHI like fatty acid binding protein genes encode homologous CHI like fatty acid binding proteins. Because of the degeneracy of the genetic code, the percentage of identity or similarity at which homology can be detected can be substantially lower than for the encoded polypeptides.

Sequence Comparison, Identity, and Homology

“Identity” or “similarity” in the context of two or more nucleic acid or polypeptide sequences, refers to the degree of sequence relatedness of the sequences. Typically, the sequences are aligned for maximum correspondence, and the percent identity or similarity is measured using a commonly available sequence comparison algorithm, e.g., as described below (other algorithms are available to persons of skill and can readily be substituted). Similarity can also be determined simply by visual inspection. Preferably, “identity” or “similarity” exists over a region of the sequences that is at least about 50 residues in length, more preferably over a region of at least about 100 residues, and most preferably the sequences are related over at least about 150 residues, or over the full length of the two sequences to be compared.

For sequence comparison and homology determination, typically one sequence acts as a reference sequence to which test sequences are compared. When using a sequence comparison algorithm, test and reference sequences are input into a computer, subsequence coordinates are designated, if necessary, and sequence algorithm program parameters are designated. The sequence comparison algorithm then calculates the percent sequence identity for the test sequence(s) relative to the reference sequence, based on the designated program parameters.

Optimal alignment of sequences for comparison can be conducted, e.g., by the local homology algorithm of Smith & Waterman, Adv. Appl. Math. 2:482 (1981), by the homology alignment algorithm of Needleman & Wunsch, J. Mol. Biol. 48:443 (1970), by the search for similarity method of Pearson & Lipman, Proc. Nat'l. Acad. Sci. USA 85:2444 (1988), by computerized implementations of these algorithms (GAP, BESTFIT, FASTA, and TFASTA in the Wisconsin Genetics Software Package, Genetics Computer Group, 575 Science Dr., Madison, Wis.), or by visual inspection (see generally, Ausubel et al., infra).

One example of an algorithm that is suitable for determining percent sequence identity and sequence similarity is the BLAST algorithm, which is described, e.g., in Altschul et al., J. Mol. Biol. 215:403-410 (1990) and by Gish et al. (1993) “Identification of protein coding regions by database similarity search” Nature Genetics 3:266-72. Software for performing BLAST analyses is publicly available through the National Center for Biotechnology Information (www(dot)ncbi(dot)nlm(dot)nih(dot)gov/) and from Washington University (Saint Louis) at www(dot)blast(dot)wustl(dot)edu/. WU-blast 2.0 (latest release date Mar. 22, 2006) provides one convenient implementation of BLAST. A variety of database and search websites such as UniProt and TAIR provide BLAST search tools to search any of a variety of publicly available databases.

In general, this algorithm involves first identifying high scoring sequence pairs (HSPs) by identifying short words of length W in the query sequence, which either match or satisfy some positive-valued threshold score T when aligned with a word of the same length in a database sequence. T is referred to as the neighborhood word score threshold (Altschul et al., supra). These initial neighborhood word hits act as seeds for initiating searches to find longer HSPs containing them. The word hits are then extended in both directions along each sequence for as far as the cumulative alignment score can be increased. Cumulative scores are calculated using, for nucleotide sequences, the parameters M (reward score for a pair of matching residues; always >0) and N (penalty score for mismatching residues; always <0). For amino acid sequences, a scoring matrix is used to calculate the cumulative score. Extension of the word hits in each direction are halted when: the cumulative alignment score falls off by the quantity X from its maximum achieved value; the cumulative score goes to zero or below, due to the accumulation of one or more negative-scoring residue alignments; or the end of either sequence is reached. The BLAST algorithm parameters W, T, and X determine the sensitivity and speed of the alignment. The BLASTN program (for nucleotide sequences) uses as defaults a wordlength (W) of 11, an expectation (E) of 10, a cutoff of 100, M=5, N=−4, and a comparison of both strands. For amino acid sequences, the BLASTP program uses as defaults a wordlength (W) of 3, an expectation (E) of 10, and the BLOSUM62 scoring matrix (see Henikoff & Henikoff (1989) Proc. Natl. Acad. Sci. USA 89:10915).

In addition to calculating percent sequence identity, the BLAST algorithm also performs a statistical analysis of the similarity between two sequences (see, e.g., Karlin & Altschul, Proc. Nat'l. Acad. Sci. USA 90:5873-5787 (1993)). One measure of similarity provided by the BLAST algorithm is the smallest sum probability (P(N)), which provides an indication of the probability by which a match between two nucleotide or amino acid sequences would occur by chance. For example, a nucleic acid is considered similar to a reference sequence if the smallest sum probability in a comparison of the test nucleic acid to the reference nucleic acid is less than about 0.1, more preferably less than about 0.01, and most preferably less than about 0.001.

Details of a (TAIR) blast search of AT287, AT396 and AT287 against the UniProt Plant Proteins database is presented in Example 2.

Generation of Expression Vectors, Transgenic Cells and Transgenic Plants

The present invention also relates to host cells and organisms which comprise recombinant nucleic acids corresponding to CHI like fatty acid binding proteins. Additionally, the invention provides for the production of recombinant polypeptides that provide improved flux through one or more fatty acid biosynthesis pathways.

General texts which describe molecular biological techniques for the cloning and manipulation of nucleic acids and production of encoded polypeptides include Berger and Kimmel, Guide to Molecular Cloning Techniques, Methods in Enzymology volume 152 Academic Press, Inc., San Diego, Calif. (Berger); Sambrook et al., Molecular Cloning—A Laboratory Manual (3rd Ed.). Vol. 1-3, Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y., 2001 (“Sambrook”) and Current Protocols in Molecular Biology, F. M. Ausubel et al., eds., Current Protocols, a joint venture between Greene Publishing Associates, Inc. and John Wiley & Sons, Inc., (supplemented through the current date) (“Ausubel”)). These texts describe mutagenesis, the use of expression vectors, promoters and many other relevant topics related to, e.g., the generation of clones that comprise nucleic acids of interest, e.g., CHI like fatty acid binding proteins and coding genes.

Host cells (plants, mammals, bacteria or others) are genetically engineered (e.g., transduced, transfected, transformed, etc.) with the vectors of this invention (e.g., vectors, such as expression vectors which comprise an ORF derived from or related to a CHI like fatty acid binding protein) which can be, for example, a cloning vector, a shuttle vector or an expression vector. Such vectors are, for example, in the form of a plasmid, a phagemid, an agrobacterium, a virus, a naked polynucleotide (linear or circular), or a conjugated polynucleotide. Vectors to be expressed in eukaryotes can first be introduced into bacteria, especially for the purpose of propagation, expansion and CHI like fatty acid binding protein production (e.g., for making crystals, etc.). The vectors are also optionally introduced into plant tissues, cultured plant cells or plant protoplasts by a variety of standard methods known in the art, including but not limited to electroporation (From et al. (1985) Proc. Natl. Acad. Sci. USA 82; 5824), infection by viral vectors such as cauliflower mosaic virus (CaMV) (Hohn et al. (1982) Molecular Biology of Plant Tumors (Academic Press, New York, pp. 549-560; Howell U.S. Pat. No. 4,407,956), high velocity ballistic penetration by small particles with the nucleic acid either within the matrix of small beads or particles, or on the surface (Klein et al. (1987) Nature 327; 70), use of pollen as vector (WO 85/01856), or use of Agrobacterium tumefaciens or A. rhizogenes carrying a T-DNA plasmid in which DNA fragments are cloned. The T-DNA plasmid is transmitted to plant cells upon infection by Agrobacterium tumefaciens, and a portion is stably integrated into the plant genome (Horsch et al. (1984) Science 233; 496; Fraley et al. (1983) Proc. Natl. Acad. Sci. USA 80; 4803). Additional details regarding nucleic acid introduction methods are found in Sambrook, Berger and Ausubel, infra. The method of introducing a nucleic acid of the present invention into a host cell is not critical to the instant invention, and it is not intended that the invention be limited to any particular method for introducing exogenous genetic material into a host cell. Thus, any suitable method, e.g., including but not limited to the methods provided herein, which provides for effective introduction of a nucleic acid into a cell or protoplast can be employed and finds use with the invention.

The engineered host cells can be cultured in conventional nutrient media modified as appropriate for such activities as, for example, activating promoters or selecting transformants. These cells can optionally be cultured into transgenic plants. In addition to Sambrook, Berger and Ausubel, all infra, Plant regeneration from cultured protoplasts is described in Evans et al. (1983) “Protoplast Isolation and Culture,” Handbook of Plant Cell Cultures 1, 124-176 (MacMillan Publishing Co., New York; Davey (1983) “Recent Developments in the Culture and Regeneration of Plant Protoplasts,” Protoplasts, pp. 12-29, (Birkhauser, Basel); Dale (1983) “Protoplast Culture and Plant Regeneration of Cereals and Other Recalcitrant Crops,” Protoplasts pp. 31-41, (Birkhauser, Basel); Binding (1985) “Regeneration of Plants,” Plant Protoplasts, pp. 21-73, (CRC Press, Boca Raton, Fla.). Additional details regarding plant cell culture and regeneration include Payne et al. (1992) Plant Cell and Tissue Culture in Liquid Systems John Wiley & Sons, Inc. New York, N.Y.; Gamborg and Phillips (eds) (1995) Plant Cell, Tissue and Organ Culture; Fundamental Methods Springer Lab Manual, Springer-Verlag (Berlin Heidelberg New York) and Plant Molecular Biology (1993) R. R. D. Croy, Ed. Bios Scientific Publishers, Oxford, U.K. ISBN 0 12 198370 6. Cell culture media in general are also set forth in Atlas and Parks (eds) The Handbook of Microbiological Media (1993) CRC Press, Boca Raton, Fla. Additional information for cell culture is found in available commercial literature such as the Life Science Research Cell Culture Catalogue (1998) from Sigma-Aldrich, Inc (St Louis, Mo.) (“Sigma-LSRCCC”) and, e.g., the Plant Culture Catalogue and supplement (e.g., 1997 or later) also from Sigma-Aldrich, Inc (St Louis, Mo.) (“Sigma-PCCS”).

The present invention also relates to the production of transgenic organisms, which may be bacteria, yeast, fungi, animals (e.g., mammals) or plants, transduced with the nucleic acids of the invention (e.g., nucleic acids comprising the CHI like fatty acid binding proteins or genes as noted herein). A thorough discussion of techniques relevant to bacteria, unicellular eukaryotes and cell culture is found in references enumerated herein and are briefly outlined as follows. Several well-known methods of introducing target nucleic acids into bacterial cells are available, any of which may be used in the present invention. These include: fusion of the recipient cells with bacterial protoplasts containing the DNA, treatment of the cells with liposomes containing the DNA, electroporation, projectile bombardment (biolistics), carbon fiber delivery, and infection with viral vectors (discussed further, below), etc. Bacterial cells can be used to amplify the number of plasmids containing DNA constructs of this invention. The bacteria are grown to log phase and the plasmids within the bacteria can be isolated by a variety of methods known in the art (see, for instance, Sambrook). In addition, a plethora of kits are commercially available for the purification of plasmids from bacteria. For their proper use, follow the manufacturer's instructions (see, for example, EasyPrep™, FlexiPrep™, both from Pharmacia Biotech; StrataClean™, from Stratagene; and, QIAprep™ from Qiagen). The isolated and purified plasmids are then further manipulated to produce other plasmids, used to transfect plant cells or incorporated into Agrobacterium tumefaciens related vectors to infect plants. Typical vectors contain transcription and translation terminators, transcription and translation initiation sequences, and promoters useful for regulation of the expression of the particular target nucleic acid. The vectors optionally comprise generic expression cassettes containing at least one independent terminator sequence, sequences permitting replication of the cassette in eukaryotes, or prokaryotes, or both, (e.g., shuttle vectors) and selection markers for both prokaryotic and eukaryotic systems. Vectors are suitable for replication and integration in prokaryotes, eukaryotes, or preferably both. See, Giliman & Smith (1979) Gene 8:81; Roberts et al. (1987) Nature 328:731; Schneider et al. (1995) Protein Expr. Purif. 6435:10; Ausubel, Sambrook, Berger (all infra). A catalogue of Bacteria and Bacteriophages useful for cloning is provided, e.g., by the ATCC, e.g., The ATCC Catalogue of Bacteria and Bacteriophage (1992) Gherna et al. (eds) published by the ATCC. Additional basic procedures for sequencing, cloning and other aspects of molecular biology and underlying theoretical considerations are also found in Watson et al. (1992) Recombinant DNA, Second Edition, Scientific American Books, NY. In addition, essentially any nucleic acid (and virtually any labeled nucleic acid, whether standard or non-standard) can be custom or standard ordered from any of a variety of commercial sources, such as the Midland Certified Reagent Company (Midland, Tex.), The Great American Gene Company (Ramona, Calif.), ExpressGen Inc. (Chicago, Ill.), Operon Technologies Inc. (Alameda, Calif.) and many others.

Additional Details for Introducing Nucleic Acids into Plants.

Embodiments of the present invention include the production of transgenic plants comprising cloned nucleic acids, e.g., CHI like fatty acid binding protein genes. Techniques for transforming plant cells with nucleic acids are widely available and can be readily adapted to the invention. Useful general references for plant cell cloning, culture and regeneration include Jones (ed) (1995) Plant Gene Transfer and Expression Protocols—Methods in Molecular Biology, Volume 49 Humana Press Towata N.J.; Payne et al. (1992) Plant Cell and Tissue Culture in Liquid Systems John Wiley & Sons, Inc. New York, N.Y. (Payne); and Gamborg and Phillips (eds) (1995) Plant Cell, Tissue and Organ Culture; Fundamental Methods Springer Lab Manual, Springer-Verlag (Berlin Heidelberg New York) (Gamborg). Additional details regarding plant cell culture are found in Croy, (ed.) (1993) Plant Molecular Biology, Bios Scientific Publishers, Oxford, U.K.

The nucleic acid constructs of the invention, e.g., plasmids, cosmids, artificial chromosomes, which can include DNA or RNA, are introduced into plant cells, either in culture or in the organs of a plant by a variety of conventional techniques. Where the sequence is expressed, the sequence is optionally combined with transcriptional and translational initiation regulatory sequences which direct the transcription or translation of the sequence from the exogenous DNA in the intended tissues of the transformed plant.

Isolated nucleic acid acids of the present invention can be introduced into plants according to any of a variety of techniques known in the art. In addition to transformation of cells followed by regeneration, techniques for transforming a wide variety of higher plant species are also well known and described in widely available technical, scientific, and patent literature. See, for example, Weising et al. (1988) Ann. Rev. Genet. 22:421-477.

The constructs of the invention, e.g., CHI like fatty acid binding protein genes, which can be provided as components of, e.g., plasmids, phagemids, cosmids, phage, naked or variously conjugated-DNA polynucleotides, (e.g., polylysine-conjugated DNA, peptide-conjugated DNA, liposome-conjugated DNA, etc.), or artificial chromosomes, can be introduced directly into the genomic DNA of a plant or plant cell using available techniques, such as electroporation and microinjection of plant cell protoplasts, or the DNA constructs can be introduced directly to plant cells using ballistic methods, such as DNA particle bombardment.

Microinjection techniques for injecting plant, e.g., cells, embryos, callus and protoplasts, are known in the art and well described in the scientific and patent literature. For example, a number of methods are described in Jones (ed) (1995) Plant Gene Transfer and Expression Protocols—Methods in Molecular Biology, Volume 49 Humana Press, Towata, N.J., as well as in the other references noted herein and available in the literature.

For example, the introduction of DNA constructs using polyethylene glycol precipitation is described in Paszkowski, et al., EMBO J. 3:2717 (1984). Electroporation techniques are described in Fromm, et al., Proc. Natl. Acad. Sci. USA 82:5824 (1985). Ballistic transformation techniques are described in Klein, et al., Nature 327:70-73 (1987). Additional details are found in Jones (1995) and Gamborg and Phillips (1995), supra, and in U.S. Pat. No. 5,990,387.

Alternatively, and in some cases preferably, Agrobacterium mediated transformation is employed to generate transgenic plants. Agrobacterium-mediated transformation techniques, including disarming and use of binary vectors, are also well described in the scientific literature. See, for example, Horsch, et al. (1984) Science 233:496; and Fraley et al. (1984) Proc. Nat'l. Acad. Sci. USA 80:4803 and recently reviewed in Hansen and Chilton (1998) Current Topics in Microbiology 240:22 and Das (1998) Subcellular Biochemistry 29: Plant Microbe Interactions, pp 343-363.

DNA constructs are optionally combined with suitable T-DNA flanking regions and introduced into a conventional Agrobacterium tumefaciens host vector. The virulence functions of the Agrobacterium tumefaciens host will direct the insertion of the construct and adjacent marker into the plant cell DNA when the cell is infected by the bacteria. See, U.S. Pat. No. 5,591,616. Although Agrobacterium is useful primarily in dicots, certain monocots can be transformed by Agrobacterium. For instance, Agrobacterium transformation of maize is described in U.S. Pat. No. 5,550,318.

Other methods of transfection or transformation include (1) Agrobacterium rhizogenes-mediated transformation (see, e.g., Lichtenstein and Fuller (1987) In: Genetic Engineering, vol. 6, P W J Rigby, Ed., London, Academic Press; and Lichtenstein; C. P., and Draper (1985) In: DNA Cloning, Vol. II, D. M. Glover, Ed., Oxford, IRI Press; WO 88/02405, published Apr. 7, 1988, describes the use of A. rhizogenes strain A4 and its Ri plasmid along with A. tumefaciens vectors pARC8 or pARC16 (2) liposome-mediated DNA uptake (see, e.g., Freeman et al. (1984) Plant Cell Physiol. 25:1353), (3) the vortexing method (see, e.g., Kindle (1990) Proc. Natl. Acad. Sci. (USA) 87:1228.

DNA can also be introduced into plants by direct DNA transfer into pollen as described by Zhou et al. (1983) Methods in Enzymology, 101:433; D. Hess (1987) Intern Rev. Cytol. 107:367; Luo et al. (1988) Plant Mol. Biol. Reporter 6:165. Expression of polypeptide coding genes can be obtained by injection of the DNA into reproductive organs of a plant as described by Pena et al. (1987) Nature 325:274. DNA can also be injected directly into the cells of immature embryos and the desiccated embryos rehydrated as described by Neuhaus et al.(1987) Theor. Appl. Genet. 75:30; and Benbrook et al. (1986) in Proceedings Bio Expo Butterworth, Stoneham, Mass., pp. 27-54. A variety of plant viruses that can be employed as vectors are known in the art and include cauliflower mosaic virus (CaMV), geminivirus, brome mosaic virus, and tobacco mosaic virus.

Generation/Regeneration of Transgenic Plants

Transformed plant cells which are derived by any of the above transformation techniques can be cultured to regenerate a whole plant that possesses the transformed genotype and thus the desired phenotype. Such regeneration techniques rely on manipulation of certain phytohormones in a tissue culture growth medium, typically relying on a biocide and/or herbicide marker which has been introduced together with the desired nucleotide sequences. Plant regeneration from cultured protoplasts is described in Payne et al. (1992) Plant Cell and Tissue Culture in Liquid Systems John Wiley & Sons, Inc. New York, N.Y.; Gamborg and Phillips (eds) (1995) Plant Cell, Tissue and Organ Culture; Fundamental Methods Springer Lab Manual, Springer-Verlag (Berlin Heidelberg New York); Evans et al. (1983) Protoplasts Isolation and Culture, Handbook of Plant Cell Culture pp. 124-176, Macmillian Publishing Company, New York; and Binding (1985) Regeneration of Plants, Plant Protoplasts pp. 21-73, CRC Press, Boca Raton. Regeneration can also be obtained from plant callus, explants, somatic embryos (Dandekar et al. (1989) J. Tissue Cult. Meth. 12:145; McGranahan, et al. (1990) Plant Cell Rep. 8:512) organs, or parts thereof. Such regeneration techniques are described generally in Klee et al. (1987)., Ann. Rev. of Plant Phys. 38:467-486. Additional details are found in Payne (1992) and Jones (1995), both supra, and Weissbach and Weissbach, eds.(1988) Methods for Plant Molecular Biology Academic Press, Inc., San Diego, Calif. This regeneration and growth process includes the steps of selection of transformant cells and shoots, rooting the transformant shoots and growth of the plantlets in soil. These methods are adapted to the invention to produce transgenic plants bearing CHI like fatty acid binding protein genes.

In addition, the regeneration of plants containing the polynucleotide of the present invention and introduced by Agrobacterium into cells of leaf explants can be achieved as described by Horsch et al. (1985) Science 227:1229-1231. In this procedure, transformants are grown in the presence of a selection agent and in a medium that induces the regeneration of shoots in the plant species being transformed as described by Fraley et al. (1983) Proc. Natl. Acad. Sci. (U.S.A.) 80:4803. This procedure typically produces shoots within two to four weeks and these transformant shoots are then transferred to an appropriate root-inducing medium containing the selective agent and an antibiotic to prevent bacterial growth. Transgenic plants of the present invention may be fertile or sterile.

It is not intended that plant transformation and expression of polypeptides that provide improved flux through a fatty acid pathway, as provided by the present invention, be limited to any particular plant species. Indeed, it is contemplated that CHI like fatty acid binding proteins can provide for lipid metabolism engineering when transformed and expressed in any agronomically and horticulturally important species. Such species include dicots, e.g., of the families: Leguminosae (including pea, beans, lentil, peanut, yam bean, cowpeas, velvet beans, soybean, clover, alfalfa, lupine, vetch, lotus, sweet clover, wisteria, and sweetpea); and, Compositae (the largest family of vascular plants, including at least 1,000 genera, including important commercial crops such as sunflower), as well as monocots, such as from the family Graminae. Plants of the Rosaciae are also preferred targets.

Additionally, preferred targets for modification with the nucleic acids of the invention, as well as those specified above, include plants from the genera: Agrostis, Allium, Antirrhinum, Apium, Arachis, Asparagus, Atropa, Avena, Bambusa, Brassica, Bromus, Browaalia, Camellia, Cannabis, Capsicum, Cicer, Chenopodium, Chichorium, Citrus, Coffea, Coix, Cucumis, Curcubita, Cynodon, Dactylis, Datura, Daucus, Digitalis, Dioscorea, Elaeis, Eleusine, Festuca, Fragaria, Geranium, Glycine, Helianthus, Heterocallis, Hevea, Hordeum, Hyoscyamus, Ipomoea, Lactuca, Lens, Lilium, Linum, Lolium, Lotus, Lycopersicon, Majorana, Malus, Mangifera, Manihot, Medicago, Nemesia, Nicotiana, Onobrychis, Oryza, Panicum, Pelargonium, Pennisetum, Petunia, Pisum, Phaseolus, Phleum, Poa, Prunus, Ranunculus, Raphanus, Ribes, Ricinus, Rubus, Saccharum, Salpiglossis, Secale, Senecio, Setaria, Sinapis, Solanum, Sorghum, Stenotaphrum, Theobroma, Trifolium, Trigonella, Triticum, Vicia, Vigna, Vitis, Zea, the Olyreae, and the Pharoideae, and many others.

Common crop plants which are targets of the present invention include: Arabidopsis thalina, Brassica naupus, Brassica juncea, Zea mays, soybean, sunflower, safflower, rapeseed, tobacco, canola, peas, beans, lentils, peanuts, yam beans, cowpeas, velvet beans, clover, alfalfa, lupine, vetch, sweet clover, sweetpea, field pea, fava bean, broccoli, Brussels sprouts, cabbage, cauliflower, kale, kohlrabi, celery, lettuce, carrot, onion, olive, pepper, potato, eggplant and tomato.

Additional Details Regarding Expression Cassettes

In construction of a recombinant expression cassette of the invention, a plant promoter fragment is optionally employed which directs expression of a nucleic acid in any or all tissues of a regenerated plant. Indeed, in one application, CHI like fatty acid binding protein genes are desirably constitutively expressed, thereby increasing flux through one or more fatty acid synthesis pathways. Examples of constitutive promoters include the cauliflower mosaic virus (CaMV) 35S transcription initiation region, the 1′- or 2′-promoter derived from T-DNA of Agrobacterium tumefaciens, and other transcription initiation regions from various plant genes known to those of skill. Alternatively, the plant promoter may direct expression of the polynucleotide of the invention in a specific tissue (tissue-specific promoters), such as a fruit, seed or other site where oils are typically produced and/or sequestered, or may be otherwise under more precise environmental control (inducible promoters). Examples of tissue-specific promoters under developmental control include promoters that initiate transcription only in certain tissues, such as fruit, seeds or flowers.

Any of a number of promoters which direct transcription in plant cells can be suitable. The promoter can be either constitutive or inducible. In addition to the promoters noted above, promoters of bacterial origin that operate in plants include the octopine synthase promoter, the nopaline synthase promoter and other promoters derived from native Ti plasmids. See, Herrara-Estrella et al. (1983), Nature, 303:209. Viral promoters include the 34S and 19S RNA promoters of cauliflower mosaic virus. See, Odell et al. (1985) Nature, 313:810. Other plant promoters include Kunitz trypsin inhibitor promoter (KTI), SCP1, SUP, UCD3, the ribulose-1,3-bisphosphate carboxylase small subunit promoter and the phaseolin promoter. The promoter sequence from the E8 gene and other genes may also be used. The isolation and sequence of the E8 promoter is described in detail in Deikman and Fischer (1988) EMBO J. 7:3315. Many other promoters are in current use and can be coupled to an exogenous DNA sequence to direct expression of the nucleic acid.

If expression of a polypeptide from a CHI like fatty acid binding protein gene is desired, a polyadenylation region at the 3′-end of the coding region can be included in the recombinant construct. The polyadenylation region can be derived from the natural gene, from a variety of other plant genes, or from, e.g., T-DNA.

The expression vector comprising cassette sequences (e.g., promoters or coding regions) and genes encoding expression products and transgenes of the invention will typically also include a marker that confers an easily selectable, or alternatively, a screenable, phenotype on plant cells. For example, the marker can encode biocide tolerance, particularly antibiotic tolerance, such as tolerance to kanamycin, G418, bleomycin, hygromycin, or herbicide tolerance, such as tolerance to chlorosluforon, or phosphinothricin (the active ingredient in the herbicides bialaphos or Basta). See, e.g., Padgette et al. (1996) In: Herbicide-Resistant Crops (Duke, ed.), pp 53-84, CRC Lewis Publishers, Boca Raton (“Padgette, 1996”). For example, crop selectivity to specific herbicides can be conferred by engineering genes into crops that encode appropriate herbicide metabolizing enzymes from other organisms, such as microbes. See, Vasil (1996) In: Herbicide-Resistant Crops (Duke, ed.), pp 85-91, CRC Lewis Publishers, Boca Raton) (“Vasil”, 1996).

One of skill will recognize that after a recombinant expression cassette from such a vector is stably incorporated in a transgenic plant and confirmed to be operable, it can be introduced into other plants by sexual crossing. Any of a number of standard breeding techniques can be used, depending upon the species to be crossed. In vegetatively propagated crops, mature transgenic plants can be propagated by the taking of cuttings or by tissue culture techniques to produce multiple identical plants. Selection of desirable transgenics is made and new varieties are obtained and propagated vegetatively for commercial use. In seed propagated crops, mature transgenic plants can be self crossed to produce a homozygous inbred plant. The inbred plant produces seed containing the newly introduced heterologous nucleic acid. These seeds can be grown to produce plants that would produce the selected CHI like fatty acid binding protein producing phenotype. Parts obtained from the regenerated plant, such as flowers, seeds, leaves, branches, fruit, and the like are included in the invention. Progeny and variants, and mutants of the regenerated plants are also included within the scope of the invention, provided that these parts comprise the introduced CHI like fatty acid binding protein genes.

Transgenic or introgressed plants expressing a polynucleotide of the present invention can be screened for transmission of the nucleic acid of the present invention by, for example, standard nucleic acid detection methods (marker assisted selection) or by immunoblot protocols. Expression at the RNA level can be monitored to identify and quantify expression-positive plants. Standard techniques for RNA analysis can be employed and include RT-PCR amplification assays using oligonucleotide primers designed to amplify only heterologous or introgressed RNA templates and solution hybridization assays using marker or linked QTL specific probes. Plants can also be analyzed for protein expression, e.g., by Western immunoblot analysis using antibodies that recognize the encoded CHI like fatty acid binding protein. In addition, in situ hybridization and immunocytochemistry according to standard protocols can be done using heterologous nucleic acid specific polynucleotide probes and antibodies, respectively, to localize sites of expression within transgenic tissue. Generally, a number of transgenic lines are usually screened for the incorporated nucleic acid to identify and select plants with the most appropriate expression profiles.

A preferred embodiment of the invention is a transgenic plant that is homozygous for the added heterologous CHI like fatty acid binding protein nucleic acid; e.g., a transgenic plant that contains two added nucleic acid sequence copies of the CHI like fatty acid binding protein genes, e.g., such a gene at the same locus on each chromosome of a homologous chromosome pair. A homozygous transgenic plant can be obtained by sexually mating (self-fertilizing) a heterozygous transgenic plant that contains a single added heterologous nucleic acid, germinating some of the seed produced and analyzing the resulting plants produced for altered expression of a polynucleotide of the present invention relative to a control plant (e.g., a native, non-transgenic plant). Back-crossing to a parental plant and out-crossing with a non-transgenic plant can be used to introgress the heterologous nucleic acid into a selected background (e.g., an elite or exotic plant line).

Additional Details Regarding Transgenic Animals

In addition to making transgenic plants, transgenic livestock or domesticated animals can be made recombinant for a given polypeptide, or a modified form thereof, thereby changing the fat content or feeding behavior of the transgenic animal, e.g., to enhance yield of a domesticated or livestock animal. Xenopus and insect cells are also useful targets for modification, due to the ease with which such cells can be grown, studied and manipulated.

A transgenic animal is typically an animal that has had DNA introduced into one or more of its cells artificially. This is most commonly done in one of two ways. First, DNA can be integrated randomly by injecting it into the pronucleus of a fertilized ovum. In this case, the DNA can integrate anywhere in the genome. In this approach, there is no need for homology between the injected DNA and the host genome. Second, targeted insertion can be accomplished by introducing heterologous DNA into embryonic stem (ES) cells and selecting for cells in which the heterologous DNA has undergone homologous recombination with homologous sequences of the cellular genome. Typically, there are several kilobases of homology between the heterologous and genomic DNA, and positive selectable markers (e.g., antibiotic resistance genes) are included in the heterologous DNA to provide for selection of transformants. In addition, negative selectable markers (e.g., “toxic” genes such as barnase) can be used to select against cells that have incorporated DNA by non-homologous recombination (i.e., random insertion).

One common use of targeted insertion of DNA is to make knock-out or transgenic mice. Typically, homologous recombination is used to insert a selectable gene driven by a constitutive promoter into an essential exon of the gene that one wishes to disrupt (e.g., the first coding exon). To accomplish this, the selectable marker is flanked by large stretches of DNA that match the genomic sequences surrounding the desired insertion point. Once this construct is electroporated into ES cells, the cells' own machinery performs the homologous recombination. To make it possible to select against ES cells that incorporate DNA by non-homologous recombination, it is common for targeting constructs to include a negatively selectable gene outside the region intended to undergo recombination (typically the gene is cloned adjacent to the shorter of the two regions of genomic homology). Because DNA lying outside the regions of genomic homology is lost during homologous recombination, cells undergoing homologous recombination cannot be selected against, whereas cells undergoing random integration of DNA often can. A commonly used gene for negative selection is the herpes virus thymidine kinase gene, which confers sensitivity to the drug gancyclovir.

Following positive selection and negative selection if desired, ES cell clones are screened for incorporation of the construct into the correct genomic locus. Typically, one designs a targeting construct so that a band normally seen on a Southern blot or following PCR amplification becomes replaced by a band of a predicted size when homologous recombination occurs. Since ES cells are diploid, only one allele is usually altered by the recombination event so, when appropriate targeting has occurred, one usually sees bands representing both wild type and targeted alleles.

The embryonic stem (ES) cells that are used for targeted insertion are derived from the inner cell masses of blastocysts (early mouse embryos). These cells are pluripotent, meaning they can develop into any type of tissue.

Once positive ES clones have been grown up and frozen, the production of transgenic animals can begin. Donor females are mated, blastocysts are harvested, and several ES cells are injected into each blastocyst. Blastocysts are then implanted into a uterine horn of each recipient. By choosing an appropriate donor strain, the detection of chimeric offspring (i.e., those in which some fraction of tissue is derived from the transgenic ES cells) can be as simple as observing hair and/or eye color. If the transgenic ES cells do not contribute to the germline (sperm or eggs), the transgene cannot be passed on to offspring.

Isolating CHI Like Proteins from Natural or Recombinant Sources

Purification of CHI like fatty acid binding proteins can be accomplished using known techniques. Generally, cells expressing the proteins (naturally or by recombinant methods) are lysed, crude purification occurs to remove debris and some contaminating proteins, followed by chromatography to further purify the protein to the desired level of purity. Cells can be lysed by known techniques such as homogenization, sonication, detergent lysis and freeze-thaw techniques. Crude purification can occur using ammonium sulfate precipitation, centrifugation or other known techniques. Suitable chromatography includes anion exchange, cation exchange, high performance liquid chromatography (HPLC), gel filtration, affinity chromatography, hydrophobic interaction chromatography, etc. Well known techniques for refolding proteins can be used to obtain the active conformation of the protein when the protein is denatured during recombinant or natural synthesis, isolation or purification.

In general, CHI like fatty acid binding proteins can be purified, either partially (e.g., achieving a 5×, 10×, 100×, 500×, or 1000× or greater purification), or even substantially to homogeneity (e.g., where the protein is the main component of a solution, typically excluding the solvent (e.g., water, crystallization buffer, DMSO, or the like) and buffer components (e.g., salts and stabilizers) that the polypeptide is suspended in, e.g., if the polypeptide is in a liquid phase), according to standard procedures known to and used by those of skill in the art. Accordingly, polypeptides of the invention can be recovered and purified by any of a number of methods well known in the art, including, e.g., ammonium sulfate or ethanol precipitation, acid or base extraction, column chromatography, affinity column chromatography, anion or cation exchange chromatography, phosphocellulose chromatography, hydrophobic interaction chromatography, hydroxylapatite chromatography, lectin chromatography, gel electrophoresis and the like. Protein refolding steps can be used, as desired, in making correctly folded mature proteins. High performance liquid chromatography (HPLC), affinity chromatography or other suitable methods can be employed in final purification steps where high purity is desired. In one embodiment, antibodies made against CHI like fatty acid binding proteins are used as purification reagents, e.g., for affinity-based purification. Once purified, partially or to homogeneity, as desired, the polypeptides are optionally used e.g., as assay components, reagents, crystallization materials, or, e.g., as immunogens for antibody production.

In addition to other references noted herein, a variety of purification/protein purification methods are well known in the art, including, e.g., those set forth in R. Scopes, Protein Purification, Springer-Verlag, N.Y. (1982); Deutscher, Methods in Enzymology Vol. 182: Guide to Protein Purification, Academic Press, Inc. N.Y. (1990); Sandana (1997) Bioseparation of Proteins, Academic Press, Inc.; Bollag et al. (1996) Protein Methods, 2nd Edition Wiley-Liss, NY; Walker (1996) The Protein Protocols Handbook Humana Press, N.J.; Harris and Angal (1990) Protein Purification Applications: A Practical Approach IRL Press at Oxford, Oxford, England; Harris and Angal Protein Purification Methods: A Practical Approach IRL Press at Oxford, Oxford, England; Scopes (1993) Protein Purification: Principles and Practice 3rd Edition Springer Verlag, NY; Janson and Ryden (1998) Protein Purification: Principles, High Resolution Methods and Applications, Second Edition Wiley-VCH, NY; and Walker (1998) Protein Protocols on CD-ROM Humana Press, NJ; and the references cited therein.

Those of skill in the art will recognize that, after synthesis, expression and/or purification, proteins can possess a conformation different from the desired conformations of the relevant polypeptides. For example, polypeptides produced by prokaryotic systems often are optimized by exposure to chaotropic agents to achieve proper folding. During purification from, e.g., lysates derived from E. coli, the expressed protein is optionally denatured and then renatured. This is accomplished, e.g., by solubilizing the proteins in a chaotropic agent such as guanidine HCl. In general, it is occasionally desirable to denature and reduce expressed polypeptides and then to cause the polypeptides to re-fold into the preferred conformation. For example, guanidine, urea, DTT, DTE, and/or a chaperonin can be added to a translation product of interest. Methods of reducing, denaturing and renaturing proteins are well known to those of skill in the art (see, the references above, and Debinski, et al. (1993) J. Biol. Chem., 268: 14065-14070; Kreitman and Pastan (1993) Bioconjug. Chem., 4: 581-585; and Buchner, et al., (1992) Anal. Biochem., 205: 263-270). Debinski, et al., for example, describe the denaturation and reduction of inclusion body proteins in guanidine-DTE. The proteins can be refolded in a redox buffer containing, e.g., oxidized glutathione and L-arginine. Refolding reagents can be flowed or otherwise moved into contact with the one or more polypeptide or other expression product, or vice-versa.

CHI like fatty acid binding protein nucleic acids optionally comprise a coding sequence fused in-frame to a marker sequence which, e.g., facilitates purification of the encoded polypeptide. Such purification facilitating domains include, but are not limited to, metal chelating peptides such as histidine-tryptophan modules that allow purification on immobilized metals, a sequence which binds glutathione (e.g., GST), a hemagglutinin (HA) tag (corresponding to an epitope derived from the influenza hemagglutinin protein; Wilson, I., et al. (1984) Cell 37:767), maltose binding protein sequences, the FLAG epitope utilized in the FLAGS extension/affinity purification system (Immunex Corp, Seattle, Wash.), and the like. The inclusion of a protease-cleavable polypeptide linker sequence between the purification domain and the sequence of the invention is useful to facilitate purification.

Specific example methods of purifying CHI like fatty acid binding proteins are described in the Examples sections below.

Generating and Using Crystals and Crystal Structure Information for Modifying CHI Like Fatty Acid Binding Proteins

The three-dimensional structures of proteins can be determined by x-ray crystallography. Typically, to determine the crystal structure of a protein, one or more crystals of the protein are obtained, diffraction data is collected from the crystals, and phases for the data are determined and used to calculate electronic density maps in which a model of the protein is built. Additional rounds of model building and refinement can then be carried out to produce a reasonable model of the protein's structure.

Making Chalcone Isomerase Like Protein Crystals

Proteins are typically purified prior to crystallization, e.g., as described above. Conditions for crystallizing proteins to obtain diffraction-quality crystals can be determined empirically using techniques known in the art. For example, crystallization conditions can be determined and optimized by screening a number of potential conditions, using vapor diffusion (e.g., hanging or sitting drop), microbatch, microdialysis, or similar techniques. Type and amount of precipitant (e.g., salt, polymer, and/or organic solvent), type and amount of additive, pH, temperature, etc. can be varied to identify conditions under which high quality crystals form.

See, e.g., McPherson (1999) Crystallization of Biological Macromolecules Cold Spring Harbor Laboratory, Bergfors (1999) Protein Crystallization International University Line, Mullin (1993) Crystallization Butterwoth-Heinemann, Baldock et al. (1996) “A comparison of microbatch and vapor diffusion for initial screening of crystallization conditions” J. Crystal Growth 168:170-174, Chayen (1998) “Comparative studies of protein crystallization by vapor diffusion and microbatch” Acta Cryst. D54:8-15, Chayen (1999) “Crystallization with oils: a new dimension in macromolecular crystal growth” J. Crystal Growth 196:434-441, Page et al. (2003) “Shotgun crystallization strategy for structural genomics: an optimized two-tiered crystallization screen against the Thermotoga maritima proteome” Acta Crystallogr. D Biol. Crystallogr. 59:1028, Kimber et al. (2003) “Data mining crystallization databases: knowledge-based approaches to optimize protein crystal screens” Proteins 51:562, and Newman et al. (2005) “Towards rationalization of crystallization screening for small- to medium-sized academic laboratories: the PACT/JCG+ strategy” Acta. Cryst. D61:1426.

Sparse matrix screening is described, e.g., in Jancarik and Kim (1991) “Sparse matrix sampling: a screening method for crystallization of proteins” J. Appl. Cryst. 24:409-411. Pre-formatted reagents for crystallization screening are commercially available, e.g., from Qiagen (www(dot)qiagen(dot)com) and Hampton Research (www(dot)hamptonresearch(dot)com). Screening is optionally automated, for example, using a robotic reagent dispensing platform. Specific examples of crystallization conditions for two chalcone isomerase like proteins are described in the Examples sections below.

Crystal Structure Determination

Techniques for crystal structure determination are well known. See, for example, Stout and Jensen (1989) X-ray structure determination: a practical guide. 2nd Edition Wiley Publishers, New York; Ladd and Palmer (1993) Structure determination by X-ray crystallography, 3rd Edition Plenum Press, New York; Blundell and Johnson (1976) Protein Crystallography Academic Press, New York; Glusker and Trueblood (1985) Crystal structure analysis: A primer, 2nd Ed. Oxford University Press, New York; International Tables for Crystallography, Vol. F. Crystallography of Biological Macromolecules; McPherson (2002) Introduction to Macromolecular Crystallography Wiley-Liss; McRee and David (1999) Practical Protein Crystallography, Second Edition Academic Press; Drenth (1999) Principles of Protein X-Ray Crystallography (Springer Advanced Texts in Chemistry) Springer-Verlag; Fanchon and Hendrickson (1991) Crystallographic Computing, Volume 5 IUCr/Oxford University Press; and Murthy (1996) Crystallographic Methods and Protocols Humana Press.

In brief, once diffraction-quality crystals of the protein have been obtained, diffraction data is collected at one or more wavelengths. The wavelength at which the diffraction data is collected can be essentially any convenient wavelength. For example, data can be conveniently collected using an in-house generator with a copper anode at the CuKα wavelength of 1.5418 Å. Alternatively or in addition, data can be collected at any of a variety of wavelengths at a synchrotron or other tunable source. For example, data is optionally collected at a wavelength selected to maximize anomalous signal from the particular heavy atom incorporated in the protein, minimize radiation damage to the protein crystal, and/or the like.

The diffraction data is then processed and used to model the protein's structure. When the structure of a related protein is already known, the structure can be solved by molecular replacement. As another example, the protein can be derivatized with one or more heavy atoms to permit phase determination and structure solution, for example, by multiple isomorphous replacement (MIR), single isomorphous replacement (SIR), multiple isomorphous replacement with anomalous signal (MIRAS), single isomorphous replacement with anomalous signal (SIRAS), multiwavelength anomalous dispersion (MAD), or single wavelength anomalous dispersion (SAD) methods.

For example, in SAD phasing the structure of the protein is determined by a process that comprises collecting diffraction data from the heavy atom-containing protein crystal at a single wavelength and measuring anomalous differences between Friedel mates, which result from the presence of the heavy atom in the crystal. In brief, collection of diffraction data involves measuring the intensities of a large number of reflections produced by exposure of one or more protein crystals to a beam of x-rays. Each reflection is identified by indices h, k, and l. Typically, the intensities of Friedel mates (pairs of reflections with indices h,k,l and −h,−k,−l) are the same. However, when a heavy atom is present in the protein crystal and the wavelength of the x-rays used is near an absorption edge for that heavy atom, anomalous scattering by the heavy atom results in differences between the intensities of certain Friedel mates. These anomalous differences can be used to calculate phases that, in combination with the measured intensities, permit calculation of an electron density map into which a model of the protein structure can be built.

As another example, MAD phasing can be used. Here the structure of the protein is determined by a process that comprises collecting diffraction data from the heavy atom-containing protein crystal at two or more wavelengths and measuring dispersive differences between data collected at different wavelengths. For example, data is optionally collected at two wavelengths, e.g., at the point of inflection of the absorption curve of the heavy atom and at a remote wavelength away from the absorption edge, e.g., utilizing a synchrotron as the radiation source.

Suitable heavy atom derivatives for SIR, MIR, SAD, MAD, or similar techniques can be obtained when necessary by methods well known in the art. For example, crystals of the native protein can be soaked in solutions containing the desired heavy atom(s). As another example, heavy atom containing amino acids such as selenomethionine, selenocysteine, or telluromethionine can be incorporated into the protein before the protein is purified and crystallized. See, e.g., Dauter et al. (2000) “Novel approach to phasing proteins: derivatization by short cryo-soaking with halides” Acta Crystallogr D 56(Pt 2):232-237, Nagem et al. (2001) “Protein crystal structure solution by fast incorporation of negatively and positively charged anomalous scatterers” Acta Crystallogr D 57:996-1002), Boles et al. (1994) “Bio-incorporation of telluromethionine into buried residues of dihydrofolate reductase” Nat Struct Biol 1:283-284, Budisa et al. (1997) “Bioincorporation of telluromethionine into proteins: a promising new approach for X-ray structure analysis of proteins” J Mol Biol 270:616-623, and Strub et al. (2003) “Selenomethionine and selenocysteine double labeling strategy for crystallographic phasing” Structure 11:1359-67.

A variety of programs to facilitate data collection, phase determination, model building and refinement, and the like are publicly available. Examples include, but are not limited to, the HKL2000 package (Otwinowski and Minor (1997) “Processing of X-ray Diffraction Data Collected in Oscillation Mode” Methods in Enzymology 276:307-326), the CCP4 package (Collaborative Computational Project (1994) “The CCP4 suite: programs for protein crystallography” Acta Crystallogr D 50:760-763), SOLVE and RESOLVE (Terwilliger and Berendzen (1999) Acta Crystallogr D 55 (Pt 4):849-861), SHELXS and SHELXD (Schneider and Sheldrick (2002) “Substructure solution with SHELXD” Acta Crystallogr D Biol Crystallogr 58:1772-1779), Refmac5 (Murshudov et al. (1997) “Refinement of Macromolecular Structures by the Maximum-Likelihood Method” Acta Crystallogr D 53:240-255 and Vagin et al. (2004) Acta Crystallogr D Biol Crystallogr 60:2184-95), CNS (Brunger et al. (1998) Acta Crystallogr D Biol Crystallogr 54 (Pt 5):905-21), PRODRG (van Aalten et al. (1996) “PRODRG, a program for generating molecular topologies and unique molecular descriptors from coordinates of small molecules” J Comput Aided Mol Des 10:255-262), and O (Jones et al. (1991) “Improved methods for building protein models in electron density maps and the location of errors in these models” Acta Crystallogr A 47 (Pt 2):110-119).

Specific examples of determination of chalcone isomerase like protein structures are described in the Examples sections below.

Structure-Based Engineering of Chalcone Isomerase Like Proteins

Structural data for a chalcone isomerase like protein can be used to conveniently identify amino acid residues as candidates for mutagenesis to create variant chalcone isomerase like proteins having modified fatty acid binding or transport activity. For example, analysis of the three-dimensional structure of a chalcone isomerase like protein can identify residues that sterically hinder access to the binding pocket by a fatty acid; such residues can be mutated to increase access to the pocket. Similarly, residues can be identified that can be mutated to introduce a feature complementary to a desired fatty acid ligand, e.g., by adding or altering charge, hydrophobicity, size, and/or the like.

The structure of a given chalcone isomerase like protein, optionally complexed to a fatty acid ligand, can be directly determined as described herein by x-ray crystallography or by NMR spectroscopy. Alternatively, the structure of a chalcone isomerase like protein can be modeled based on homology with a chalcone isomerase like protein whose structure has already been determined, for example, either of the structures described herein in the Examples sections.

The binding pocket of the chalcone isomerase like protein can be identified, for example, by examination of a protein-ligand co-complex structure, homology with other chalcone isomerase like proteins, biochemical analysis of mutant proteins, and/or the like. The position of a fatty acid ligand in the binding pocket can be modeled, for example, by projecting the location of features of the ligand based on the previously determined location of another ligand in the binding pocket.

Such modeling of the ligand in the binding pocket can involve simple visual inspection of a model of the chalcone isomerase like protein, for example, using molecular graphics software such as the PyMOL viewer (open source, freely available on the World Wide Web at (www.)pymol.org) or Insight II (commercially available from Accelrys at (www(dot)accelrys(dot)com/products/insight). Alternatively, modeling of the ligand in the binding pocket of the chalcone isomerase like protein or a putative mutant chalcone isomerase like protein, for example, can involve computer-assisted docking, molecular dynamics, free energy minimization, and/or like calculations. Such modeling techniques have been well described in the literature; see, e.g., Babine and Abdel-Meguid (eds.) (2004) Protein Crystallography in Drug Design, Wiley-VCH, Weinheim; Lyne (2002) “Structure-based virtual screening: An overview” Drug Discov. Today 7:1047-1055; Molecular Modeling for Beginners, at (www(dot)usm(dot)maine(dot)edu/˜rhodes/SPVTut/index(dot)html; and Methods for Protein Simulations and Drug Design at (www(dot)dddc(dot)ac(dot)cn/embo04; and references therein. Software to facilitate such modeling is widely available, for example, the CHARMm simulation package, available academically from Harvard University or commercially from Accelrys (at www(dot)accelrys(dot)com), the Discover simulation package (included in Insight II, supra), and Dynama (available at (www(dot)cs(dot)gsu(dot)edu/˜cscrwh/progs/progs(dot)html). See also an extensive list of modeling software at (www(dot)netsci(dot)org/Resources/Software/Modeling/MMMD/top(dot)html.

Visual inspection and/or computational analysis of a chalcone isomerase like protein model can identify relevant features of the binding region, including, for example, residues that can sterically inhibit entry of a ligand into the binding pocket (e.g., residues undesirably close to the projected location of one or more atoms within the ligand when the ligand is bound to the chalcone isomerase like protein). Such a residue can, for example, be deleted or replaced with a residue having a smaller side chain; for example, many residues can be conveniently replaced with a residue having similar characteristics but a shorter amino acid side chain, or, e.g., with alanine. Similarly, residues that can be altered to introduce desirable interactions with the ligand can be identified. Such a residue can be replaced with a residue that is complementary with a feature of the ligand, for example, with a charged residue (e.g., lysine, arginine, or histidine) that can electrostatically interact with an oppositely charged moiety on the ligand (e.g., a carboxylic acid group), a hydrophobic residue that can interact with a hydrophobic group on the ligand, or a residue that can hydrogen bond to the ligand (e.g., serine, threonine, histidine, asparagine, or glutamine).

Systems of the invention can include any of the various crystallographic or modeling software described above, e.g., implemented in a computer system. Systems also typically include one or more databases of crystallographic information, e.g., as set forth in the figures herein. Systems also optionally include a user input (e.g., keyboard or mouse) a user viewable display, an information storage module (e.g., disk drive or optical disk), etc. Optionally, the system can include one or more modules that assist in gathering crystallographic information, e.g., any of those noted above.

Modulating Lipid Production in Cells and Whole Organisms, Including Plants and Livestock Animals

The CHI like fatty acid binding proteins of the invention can be expressed in a cell to modify lipid production in the cell, e.g., by increasing flux through one or more lipid biosynthesis pathways. For example, CHI like fatty acid binding proteins may act as transporters of fatty acids, e.g., such as C12 to C18 saturated, or monounsaturated fatty acids, including oleic acid, lauric acid, myristic acid, palmitic acid, steric acid, etc., from an inner thalakoid membrane to the outer surface of a plant plastid. This increases the rate at which such fatty acids are reactivated to acyl-CoAs for utilization in cytosolic glycerolipid synthesis.

Accordingly, in one embodiment, lipid production is increased by expressing one or more recombinant CHI like fatty acid binding protein genes in the cell. High levels of expression are expected to increase fatty acid transport, increasing cytosolic glycerolipid synthesis. Thus, such genes can be expressed in expression cassettes that utilize strong promoters, e.g., any of the various constitutive promoters noted herein, including pol III promoters, strong Pol II promoters, etc. Strong tissue-specific promoters can also be used, e.g., where fatty acid content is desirably raised in a particular tissue (e.g., fruit, nut, seed, etc.).

A variety of plant promoters are known and available. One example database of plant promoters is PlantProm DB, an annotated collection of promoter sequences for RNA polymerase II from various plant species. See, e.g., Shahmuradov et al. (2003) “PlantProm: a database of plant promoter sequences” Nucleic Acids Research 31(1):114-117. The database was developed by Softberry in collaboration with Department of Computer Science at Royal Holloway, University of London (www(dot)softberry(dot)com/berry(dot)phtml?topic=plantprom&group=data&subgroup=plantprom). One relatively recent release of PlantProm DB contains 305 entries, including 71, 220 and 14 promoters from monocot, dicot and other plants, respectively. Another example database of suitable promoters is provided by the University of Georgia's plant genome mapping project. See, www(dot)plantgenome(dot)uga(dot)edu/links(dot)htm. Montgomery et al. (2006) “ORegAnno: an open access database and curation system for literature-derived promoters, transcription factor binding sites and regulatory variation” Bioinformatics 22(5): 637-640 describe an open access database for promoter identification from the literature. MOHANTY ET AL. (2005) “Detection and Preliminary Analysis of Motifs in Promoters of Anaerobically Induced Genes of Different Plant Species” Ann. Bot. 96(4): 669-681 describe a variety of promoters from different plant species. Xie et al. (2005) “Expression of Arabidopsis MIRNA Genes” Plant Physiology 138(4): 2145-2154 describe promoters for Arabidopsis MIRNA Genes. Florquin et al. (2005) “Large-scale structural analysis of the core promoter in mammalian and plant genomes” Nucleic Acids Res. 33(13): 4255-4264 describe core promoters in mammalian and plant genomes. Shahmuradov et al. (2005) “Plant promoter prediction with confidence estimation” Nucleic Acids Res. 33(3): 1069-1076 provide plant promoter prediction methods for evaluating plant genomic data. Steffens et al (2004) “AthaMap: an online resource for in silico transcription factor binding sites in the Arabidopsis thaliana genome” Nucleic Acids Res. 32(90001): D368-372 describe predicted promoters in Arabidopsis thaliana. These and many other promoters and other genomic features (enhancers, etc.) are widely available to skilled practitioners. Further details regarding suitable promoters are found herein, e.g., in the section entitled “Expression Cassettes.”

In addition to raising lipid content, the invention is also useful for decreasing lipid content. For example, it may be beneficial in some instances to decrease dietary lipids in plants or livestock animals, e.g., to combat obesity, metabolic syndrome, or the like in humans that consume the plants or livestock. In these cases, plants or livestock can be engineered that comprise one or more deletion or down regulating modification of a native CHI like fatty acid binding protein gene. Optionally, this native gene can be substituted with a recombinant expression cassette that includes a recombinant CHI like fatty acid binding protein gene under the control of a quantitatively inducible promoter, e.g., to modulate expression of the recombinant gene in response to selected environmental stimuli.

Modulators of native or recombinant CHI like fatty acid binding protein genes can also be engineered into a cell or plant of interest. Many modulators of protein expression are known, including transcription factors that trans-activate expression of genes, anti-sense expression that blocks transcription or translation, and various Si-RNA types of gene modulators.

For example, use of antisense nucleic acids is well known in the art. An antisense nucleic acid has a region of complementarity to a target nucleic acid, e.g., a target CHI like fatty acid binding protein mRNA or DNA. Typically, a nucleic acid comprising a nucleotide sequence in a complementary, antisense orientation with respect to a coding (sense) sequence of an endogenous gene is introduced into a cell. The antisense nucleic acid can be RNA, DNA, a PNA or any other appropriate molecule. A duplex can form between the antisense sequence and its complementary sense sequence, resulting in inactivation of the gene. The antisense nucleic acid can inhibit gene expression by forming a duplex with an RNA transcribed from the gene, by forming a triplex with duplex DNA, etc. An antisense nucleic acid can be produced, e.g., for any gene whose coding sequence is known or can be determined by a number of well-established techniques (e.g., chemical synthesis of an antisense RNA or oligonucleotide (optionally including modified nucleotides and/or linkages that increase resistance to degradation or improve cellular uptake) or in vitro transcription). Antisense nucleic acids and their use are described, e.g., in U.S. Pat. No. 6,242,258 to Haselton and Alexander (Jun. 5, 2001) entitled “Methods for the selective regulation of DNA and RNA transcription and translation by photoactivation”; U.S. Pat. No. 6,500,615; U.S. Pat. No. 6,498,035; U.S. Pat. No. 6,395,544; U.S. Pat. No. 5,563,050; E. Schuch et al (1991) Symp Soc. Exp Biol 45:117-127; de Lange et al., (1995) Curr Top Microbiol Immunol 197:57-75; Hamilton et al. (1995) Curr Top Microbiol Immunol 197:77-89; Finnegan et al., (1996) Proc Natl Acad Sci USA 93:8449-8454; Uhlmann and A. Pepan (1990), Chem. Rev. 90:543; P. D. Cook (1991), Anti-Cancer Drug Design 6:585; J. Goodchild, Bioconjugate Chem. 1 (1990) 165; and, S. L. Beaucage and R. P. Iyer (1993), Tetrahedron 49:6123; and F. Eckstein, Ed. (1991), Oligonucleotides and Analogues—A Practical Approach, IRL Press.

Gene expression can also be inhibited by RNA silencing or interference. “RNA silencing” refers to any mechanism through which the presence of a single-stranded or, typically, a double-stranded RNA in a cell results in inhibition of expression of a target gene comprising a sequence identical or nearly identical to that of the RNA, including, but not limited to, RNA interference, repression of translation of a target mRNA transcribed from the target gene without alteration of the mRNA's stability, and transcriptional silencing (e.g., histone acetylation and heterochromatin formation leading to inhibition of transcription of the target mRNA).

The term “RNA interference” (“RNAi,” sometimes called RNA-mediated interference, post-transcriptional gene silencing, or quelling) refers to a phenomenon in which the presence of RNA, typically double-stranded RNA, in a cell results in inhibition of expression of a gene comprising a sequence identical, or nearly identical, to that of the double-stranded RNA. The double-stranded RNA responsible for inducing RNAi is called an “interfering RNA.” Expression of the gene is inhibited by the mechanism of RNAi as described below, in which the presence of the interfering RNA results in degradation of mRNA transcribed from the gene and thus in decreased levels of the mRNA and any encoded protein.

The mechanism of RNAi has been and is being extensively investigated in a number of eukaryotic organisms and cell types. See, for example, the following reviews: McManus and Sharp (2002) “Gene silencing in mammals by small interfering RNAs” Nature Reviews Genetics 3:737-747; Hutvagner and Zamore (2002) “RNAi: Nature abhors a double strand” Curr Opin Genet & Dev 200:225-232; Hannon (2002) “RNA interference” Nature 418:244-251; Agami (2002) “RNAi and related mechanisms and their potential use for therapy” Curr Opin Chem Biol 6:829-834; Tuschl and Borkhardt (2002) “Small interfering RNAs: A revolutionary tool for the analysis of gene function and gene therapy” Molecular Interventions 2:158-167; Nishikura (2001) “A short primer on RNAi: RNA-directed RNA polymerase acts as a key catalyst” Cell 107:415-418; and Zamore (2001) “RNA interference: Listening to the sound of silence” Nature Structural Biology 8:746-750. RNAi is also described in the patent literature; see, e.g., CA 2359180 by Kreutzer and Limmer entitled “Method and medicament for inhibiting the expression of a given gene”; WO 01/68836 by Beach et al. entitled “Methods and compositions for RNA interference”; WO 01/70949 by Graham et al. entitled “Genetic silencing”; and WO 01/75164 by Tuschl et al. entitled “RNA sequence-specific mediators of RNA interference.”

In brief, double-stranded RNA introduced into a cell (e.g., into the cytoplasm) is processed, for example by an RNAse II-like enzyme called Dicer, into shorter double-stranded fragments called small interfering RNAs (siRNAs, also called short interfering RNAs). The length and nature of the siRNAs produced is dependent on the species of the cell, although typically siRNAs are 21-25 nucleotides long (e.g., an siRNA may have a 19 base pair duplex portion with two nucleotide 3′ overhangs at each end). Similar siRNAs can be produced in vitro (e.g., by chemical synthesis or in vitro transcription) and introduced into the cell to induce RNAi. The siRNA becomes associated with an RNA-induced silencing complex (RISC). Separation of the sense and antisense strands of the siRNA, and interaction of the siRNA antisense strand with its target mRNA through complementary base-pairing interactions, optionally occurs. Finally, the mRNA is cleaved and degraded.

Expression of a target gene in a cell can thus be specifically inhibited by introducing an appropriately chosen double-stranded RNA into the cell. Guidelines for design of suitable interfering RNAs are known to those of skill in the art. For example, interfering RNAs are typically designed against exon sequences, rather than introns or untranslated regions. Characteristics of high efficiency interfering RNAs may vary by cell type. For example, although siRNAs may require 3′ overhangs and 5′ phosphates for most efficient induction of RNAi in Drosophila cells, in mammalian cells blunt ended siRNAs and/or RNAs lacking 5′ phosphates can induce RNAi as effectively as siRNAs with 3′ overhangs and/or 5′ phosphates (see, e.g., Czauderna et al. (2003) “Structural variations and stabilizing modifications of synthetic siRNAs in mammalian cells” Nucl Acids Res 31:2705-2716). As another example, since double-stranded RNAs greater than 30-80 base pairs long activate the antiviral interferon response in mammalian cells and result in non-specific silencing, interfering RNAs for use in mammalian cells are typically less than 30 base pairs (for example, Caplen et al. (2001) “Specific inhibition of gene expression by small double-stranded RNAs in invertebrate and vertebrate systems” Proc. Natl. Acad. Sci. USA 98:9742-9747, Elbashir et al. (2001) “Duplexes of 21-nucleotide RNAs mediate RNA interference in cultured mammalian cells” Nature 411:494-498 and Elbashir et al. (2002) “Analysis of gene function in somatic mammalian cells using small interfering RNAs” Methods 26:199-213 describe the use of 21 nucleotide siRNAs to specifically inhibit gene expression in mammalian cell lines, and Kim et al. (2005) “Synthetic dsRNA Dicer substrates enhance RNAi potency and efficacy” Nature Biotechnology 23:222-226 describes use of 25-30 nucleotide duplexes). The sense and antisense strands of a siRNA are typically, but not necessarily, completely complementary to each other over the double-stranded region of the siRNA (excluding any overhangs). The antisense strand is typically completely complementary to the target mRNA over the same region, although some nucleotide substitutions can be tolerated (e.g., a one or two nucleotide mismatch between the antisense strand and the mRNA can still result in RNAi, although at reduced efficiency). The ends of the double-stranded region are typically more tolerant to substitution than the middle; for example, as little as 15 bp (base pairs) of complementarity between the antisense strand and the target mRNA in the context of a 21 mer with a 19 bp double-stranded region has been shown to result in a functional siRNA (see, e.g., Czauderna et al. (2003) “Structural variations and stabilizing modifications of synthetic siRNAs in mammalian cells” Nucl Acids Res 31:2705-2716). Any overhangs can but need not be complementary to the target mRNA; for example, TT (two 2′-deoxythymidines) overhangs are frequently used to reduce synthesis costs.

Although double-stranded RNAs (e.g., double-stranded siRNAs) were initially thought to be required to initiate RNAi, several recent reports indicate that the antisense strand of such siRNAs is sufficient to initiate RNAi. Single-stranded antisense siRNAs can initiate RNAi through the same pathway as double-stranded siRNAs (as evidenced, for example, by the appearance of specific mRNA endonucleolytic cleavage fragments). As for double-stranded interfering RNAs, characteristics of high-efficiency single-stranded siRNAs may vary by cell type (e.g., a 5′ phosphate may be required on the antisense strand for efficient induction of RNAi in some cell types, while a free 5′ hydroxyl is sufficient in other cell types capable of phosphorylating the hydroxyl). See, e.g., Martinez et al. (2002) “Single-stranded antisense siRNAs guide target RNA cleavage in RNAi” Cell 110:563-574; Amarzguioui et al. (2003) “Tolerance for mutations and chemical modifications in a siRNA” Nucl. Acids Res. 31:589-595; Holen et al. (2003) “Similar behavior of single-strand and double-strand siRNAs suggests that they act through a common RNAi pathway” Nucl. Acids Res. 31:2401-2407; and Schwarz et al. (2002) Mol. Cell. 10:537-548.

Due to currently unexplained differences in efficiency between siRNAs corresponding to different regions of a given target mRNA, several siRNAs are typically designed and tested against the target mRNA to determine which siRNA is most effective. Interfering RNAs can also be produced as small hairpin RNAs (shRNAs, also called short hairpin RNAs), which are processed in the cell into siRNA-like molecules that initiate RNAi (see, e.g., Siolas et al. (2005) “Synthetic shRNAs as potent RNAi triggers” Nature Biotechnology 23:227-231).

The presence of RNA, particularly double-stranded RNA, in a cell can result in inhibition of expression of a gene comprising a sequence identical or nearly identical to that of the RNA through mechanisms other than RNAi. For example, double-stranded RNAs that are partially complementary to a target mRNA can repress translation of the mRNA without affecting its stability. As another example, double-stranded RNAs can induce histone methylation and heterochromatin formation, leading to transcriptional silencing of a gene comprising a sequence identical or nearly identical to that of the RNA (see, e.g., Schramke and Allshire (2003) “Hairpin RNAs and retrotransposon LTRs effect RNAi and chromatin-based gene silencing” Science 301:1069-1074; Kawasaki and Taira (2004) “Induction of DNA methylation and gene silencing by short interfering RNAs in human cells” Nature 431:211-217; and Morris et al. (2004) “Small interfering RNA-induced transcriptional gene silencing in human cells” Science 305:1289-1292).

Short RNAs called microRNAs (miRNAs) have been identified in a variety of species. Typically, these endogenous RNAs are each transcribed as a long RNA and then processed to a pre-miRNA of approximately 60-75 nucleotides that forms an imperfect hairpin (stem-loop) structure. The pre-miRNA is typically then cleaved, e.g., by Dicer, to form the mature miRNA. Mature miRNAs are typically approximately 21-25 nucleotides in length, but can vary, e.g., from about 14 to about 25 or more nucleotides. Some, though not all, miRNAs have been shown to inhibit translation of mRNAs bearing partially complementary sequences. Such miRNAs contain one or more internal mismatches to the corresponding mRNA that are predicted to result in a bulge in the center of the duplex formed by the binding of the miRNA antisense strand to the mRNA. The miRNA typically forms approximately 14-17 Watson-Crick base pairs with the mRNA; additional wobble base pairs can also be formed. In addition, short synthetic double-stranded RNAs (e.g., similar to siRNAs) containing central mismatches to the corresponding mRNA have been shown to repress translation (but not initiate degradation) of the mRNA. See, for example, Zeng et al. (2003) “MicroRNAs and small interfering RNAs can inhibit mRNA expression by similar mechanisms” Proc. Natl. Acad. Sci. USA 100:9779-9784; Doench et al. (2003) “siRNAs can function as miRNAs” Genes & Dev. 17:438-442; Bartel and Bartel (2003) “MicroRNAs: At the root of plant development?” Plant Physiology 132:709-717; Schwarz and Zamore (2002) “Why do miRNAs live in the miRNP?” Genes & Dev. 16:1025-1031; Tang et al. (2003) “A biochemical framework for RNA silencing in plants” Genes & Dev. 17:49-63; Meister et al. (2004) “Sequence-specific inhibition of microRNA- and siRNA-induced RNA silencing” RNA 10:544-550; Nelson et al. (2003) “The microRNA world: Small is mighty” Trends Biochem. Sci. 28:534-540; Scacheri et al. (2004) “Short interfering RNAs can induce unexpected and divergent changes in the levels of untargeted proteins in mammalian cells” Proc. Natl. Acad. Sci. USA 101:1892-1897; Sempere et al. (2004) “Expression profiling of mammalian microRNAs uncovers a subset of brain-expressed microRNAs with possible roles in murine and human neuronal differentiation” Genome Biology 5:R13; Dykxhoorn et al. (2003) “Killing the messenger: Short RNAs that silence gene expression” Nature Reviews Molec. and Cell Biol. 4:457-467; McManus (2003) “MicroRNAs and cancer” Semin Cancer Biol. 13:253-288; and Stark et al. (2003) “Identification of Drosophila microRNA targets” PLoS Biol. 1:E60.

The cellular machinery involved in translational repression of mRNAs by partially complementary RNAs (e.g., certain miRNAs) appears to partially overlap that involved in RNAi, although, as noted, translation of the mRNAs, not their stability, is affected and the mRNAs are typically not degraded.

The location and/or size of the bulge(s) formed when the antisense strand of the RNA binds the mRNA can affect the ability of the RNA to repress translation of the mRNA. Similarly, location and/or size of any bulges within the RNA itself can also affect efficiency of translational repression. See, e.g., the references above. Typically, translational repression is most effective when the antisense strand of the RNA is complementary to the 3′ untranslated region (3′ UTR) of the mRNA. Multiple repeats, e.g., tandem repeats, of the sequence complementary to the antisense strand of the RNA can also provide more effective translational repression; for example, some mRNAs that are translationally repressed by endogenous miRNAs contain 7-8 repeats of the miRNA binding sequence at their 3′ UTRs. It is worth noting that translational repression appears to be more dependent on concentration of the RNA than RNA interference does; translational repression is thought to involve binding of a single mRNA by each repressing RNA, while RNAi is thought to involve cleavage of multiple copies of the mRNA by a single siRNA-RISC complex.

Guidance for design of a suitable RNA to repress translation of a given target mRNA can be found in the literature (e.g., the references above and Doench and Sharp (2004) “Specificity of microRNA target selection in translational repression” Genes & Dev. 18:504-511; Rehmsmeier et al. (2004) “Fast and effective prediction of microRNA/target duplexes” RNA 10:1507-1517; Robins et al. (2005) “Incorporating structure to predict microRNA targets” Proc Natl Acad Sci 102:4006-4009; and Mattick and Makunin (2005) “Small regulatory RNAs in mammals” Hum. Mol. Genet. 14:R121-R132, among many others) and herein. However, due to differences in efficiency of translational repression between RNAs of different structure (e.g., bulge size, sequence, and/or location) and RNAs corresponding to different regions of the target mRNA, several RNAs are optionally designed and tested against the target mRNA to determine which is most effective at repressing translation of the target mRNA.

measuring Lipid Content in Plants

Lipid content is measured in plants according to standard methods. Literally hundreds of lipid analysis methods for the analysis of plant lipids are known and available. These include basic methods of detecting lipid content, such as: liquid or gas chromatography, ion exchange chromatography, mass spectrometry, multi-dimensional chromatography and spectrometry, nmr analysis, combined extraction-esterification of fatty acids, gas chromatography of diacylglycerol derivatives (derived from phospholipids), and many others. Details regarding lipid analysis methods are found in the following references: Benning, (1998) “Biosynthesis and function of the sulfolipid sulfoquinovosyl diacylglycerol” Ann. Rev. Plant Physiol. Plant Mol. Biol., 49:53-75; Benning and Ohta (2005) “Three enzyme systems for galactoglycerolipid biosynthesis are coordinately regulated in plants.” J. Biol. Chem., 280: 2397-2400; Dörmann and Benning (2002) “Galactolipids rule in seed plants.” Trends Plant Sci. 7:12-118; Frentzen (2004) “Phosphatidylglycerol and sulfoquinovosyldiacylglycerol: anionic membrane lipids and phosphate regulation.” Current Opinion in Plant Biology, 7: 270-276; Heinz (1996) “Plant glycolipids: structure, isolation and analysis.” In: Advances in Lipid Methodology—Three, pp. 211-332 (ed. W.W. Christie, Oily Press, Dundee); Ishizuka (1997) “Chemistry and functional distribution of sulfoglycolipids.” Prog. Lipid Res., 36, 245-319; Joyard and Douce (1987) “Galactolipid synthesis. In: The Biochemistry of Plants. Vol. 9. Lipids: Structure and Function” pp. 215-274 (ed. P. K. Stumpf, Academic Press, Orlando); Kates, M. (ed.) (1990) Handbook of Lipid Research 6. Glycolipids, Phosphoglycolipids and Sulfoglycolipids, (ed. M. Kates, Plenum Press, NY); and Schmid, and Ohlrogge (2002) “Lipid metabolism in plants,” In: Biochemistry of Lipids, Lipoproteins and Membranes, 4th Edition, pp. 93-126 (ed. D. E. Vance and J. Vance, Elsevier, Amsterdam). Additional details regarding lipid analysis are also found at www(dot)lipidlibrary(dot)co(dot)uk/index(dot)html and the many lipid analysis references cited therein.

Selecting Plants for Chi Like Fatty Acid Binding Polypeptide Gene Polymorphisms

Marker assisted selection (MAS) is routinely performed to select crop varieties and livestock animals for traits of interest. The development of molecular markers has facilitated mapping and selection of agriculturally important traits in essentially every plant and livestock animal of commercial interest. Markers tightly linked to genes (in this case CHI like fatty acid binding protein genes) that influence lipid phenotype are a substantial asset in the rapid identification of plant and animal lines that comprise the phenotype of interest, with the markers being used as an easily screenable proxy for the actual phenotype. Introgressing CHI like fatty acid binding protein genes into a desired cultivar (e.g., an elite crop line) or livestock breed is also facilitated by using suitable markers.

Molecular Markers and Marker Assisted Selection

A genetic map is a graphical representation of a genome (or a portion of a genome such as a single chromosome) where the distances between landmarks on the chromosome are measured by the recombination frequencies between the landmarks. A genetic landmark can be any of a variety of known polymorphic markers, for example but not limited to, molecular markers such as SSR markers, RFLP markers, or SNP markers. Furthermore, SSR markers can be derived from genomic or expressed nucleic acids (e.g., ESTs). The nature of these physical landmarks and the methods used to detect them vary, but all of these markers are physically distinguishable from each other (as well as from the plurality of alleles of any one particular marker) on the basis of polynucleotide length and/or sequence.

Although specific DNA sequences that encode proteins are generally well-conserved across a species, other regions of DNA (typically non-coding) tend to accumulate polymorphisms, and therefore, are likely to be variable between individuals of the same species. Such regions provide the basis for numerous molecular genetic markers. In general, any differentially inherited polymorphic trait (including a nucleic acid polymorphism) that segregates among progeny is a potential marker. The genomic variability can be of any origin, for example, insertions, deletions, duplications, repetitive elements, point mutations, recombination events, or the presence and sequence of transposable elements. Similarly, numerous methods for detecting molecular markers are also well-established.

The primary motivation for developing molecular marker technologies from the point of view of plant breeders has been the possibility to increase breeding efficiency through MAS. A molecular marker allele that demonstrates linkage disequilibrium with a desired phenotypic trait (e.g., a quantitative trait locus, or QTL, such as resistance to a particular disease) provides a useful tool for the selection of a desired trait in a plant or animal population. The key components to the implementation of this approach are: (i) the creation of a dense genetic map of molecular markers, (ii) the detection of QTL based on statistical associations between marker and phenotypic variability, (iii) the definition of a set of desirable marker alleles based on the results of the QTL analysis, and (iv) the use and/or extrapolation of this information to the current set of breeding germplasm to enable marker-based selection decisions to be made.

Two types of markers are frequently used in marker assisted selection protocols, namely simple sequence repeat (SSR, also known as microsatellite) markers, and single nucleotide polymorphism (SNP) markers. The term SSR refers generally to any type of molecular heterogeneity that results in length variability, and most typically is a short (up to several hundred base pairs) segment of DNA that consists of multiple tandem repeats of a two or three base-pair sequence. These repeated sequences result in highly polymorphic DNA regions of variable length due to poor replication fidelity, e.g., caused by polymerase slippage. SSRs appear to be randomly dispersed through the genome and are generally flanked by conserved regions. SSR markers can also be derived from RNA sequences (in the form of a cDNA, a partial cDNA or an EST) as well as genomic material.

The characteristics of SSR heterogeneity make them well suited for use as molecular genetic markers; namely, SSR genomic variability is inherited, is multiallelic, codominant and is reproducibly detectable. The proliferation of increasingly sophisticated amplification-based detection techniques (e.g., PCR-based) provides a variety of sensitive methods for the detection of nucleotide sequence heterogeneity. Primers (or other types of probes) are designed to hybridize to conserved regions that flank the SSR domain, resulting in the amplification of the variable SSR region. The different sized amplicons generated from an SSR region have characteristic and reproducible sizes. The different sized SSR amplicons observed from two homologous chromosomes in an individual, or from different individuals in the plant population are generally termed “marker alleles.” As long as there exists at least two SSR alleles that produce PCR products with at least two different sizes, the SSRs can be employed as a marker.

Various techniques have been developed for the detection of polymorphisms, including allele specific hybridization (ASH; see, e.g., Coryell et al., (1999) “Allele specific hybridization markers for soybean,” Theor. Appl. Genet., 98:690-696). Additional types of molecular markers are also widely used, including but not limited to expressed sequence tags (ESTs) and SSR markers derived from EST sequences, restriction fragment length polymorphism (RFLP), amplified fragment length polymorphism (AFLP), randomly amplified polymorphic DNA (RAPD) and isozyme markers. A wide range of protocols are known to one of skill in the art for detecting this variability, and these protocols are frequently specific for the type of polymorphism they are designed to detect. For example, PCR amplification, single-strand conformation polymorphisms (SSCP) and self-sustained sequence replication (3SR; see Chan and Fox, “NASBA and other transcription-based amplification methods for research and diagnostic microbiology,” Reviews in Medical Microbiology 10:185-196 [1999]).

Linkage of one molecular marker to another molecular marker is measured as a recombination frequency. In general, the closer two loci (e.g., two SSR markers) are on the genetic map, the closer they lie to each other on the physical map. A relative genetic distance (determined by crossing over frequencies, measured in centimorgans; cM) is generally proportional to the physical distance (measured in base pairs, e.g., kilobase pairs [kb] or megabasepairs [Mbp]) that two linked loci are separated from each other on a chromosome. A lack of precise proportionality between cM and physical distance can result from variation in recombination frequencies for different chromosomal regions, e.g., some chromosomal regions are recombinational “hot spots,” while others regions do not show any recombination, or only demonstrate rare recombination events. In general, the closer one marker is to another marker, whether measured in terms of recombination or physical distance, the more strongly they are linked. In some aspects, the closer a molecular marker is to a CHI like fatty acid binding protein gene that imparts a particular phenotype (e.g., increased or decreased oil production), whether measured in terms of recombination or physical distance, the better that marker serves to tag the desired phenotypic trait.

Techniques for Marker Detection

Markers corresponding to genetic polymorphisms between members of a population can be detected by methods well-established in the art (e.g., PCR-based sequence specific amplification, restriction fragment length polymorphisms (RFLPs), isozyme markers, allele specific hybridization (ASH), amplified variable sequences of the plant genome, self-sustained sequence replication, simple sequence repeat (SSR), single nucleotide polymorphism (SNP), random amplified polymorphic DNA (“RAPD”) or amplified fragment length polymorphisms (AFLP). In one additional embodiment, the presence or absence of a molecular marker is determined simply through nucleotide sequencing of the polymorphic marker region. This method is readily adapted to high throughput analysis as are the other methods noted above, e.g., using available high throughput sequencing methods such as sequencing by hybridization.

In general, the majority of genetic markers rely on one or more property of nucleic acids for their detection. For example, some techniques for detecting genetic markers utilize hybridization of a probe nucleic acid to nucleic acids corresponding to the genetic marker (e.g., amplified nucleic acids produced using genomic plant DNA as a template). Hybridization formats, including but not limited to solution phase, solid phase, mixed phase, or in situ hybridization assays are useful for allele detection. An extensive guide to the hybridization of nucleic acids is found in Tijssen (1993) Laboratory Techniques in Biochemistry and Molecular Biology—Hybridization with Nucleic Acid Probes Elsevier, New York, as well as in Sambrook, Berger and Ausubel (herein).

For example, markers that comprise restriction fragment length polymorphisms (RFLP) are detected, e.g., by hybridizing a probe which is typically a sub-fragment (or a synthetic oligonucleotide corresponding to a sub-fragment) of the nucleic acid to be detected to restriction digested genomic DNA. The restriction enzyme is selected to provide restriction fragments of at least two alternative (or polymorphic) lengths in different individuals or populations. Determining one or more restriction enzyme that produces informative fragments for each cross is a simple procedure, well known in the art. After separation by length in an appropriate matrix (e.g., agarose or polyacrylamide) and transfer to a membrane (e.g., nitrocellulose, nylon, etc.), the labeled probe is hybridized under conditions which result in equilibrium binding of the probe to the target followed by removal of excess probe by washing.

Nucleic acid probes to the marker loci can be cloned and/or synthesized. Any suitable label can be used with a probe of the invention. Detectable labels suitable for use with nucleic acid probes include, for example, any composition detectable by spectroscopic, radioisotopic, photochemical, biochemical, immunochemical, electrical, optical or chemical means. Useful labels include biotin for staining with labeled streptavidin conjugate, magnetic beads, fluorescent dyes, radiolabels, enzymes, and calorimetric labels. Other labels include ligands which bind to antibodies labeled with fluorophores, chemiluminescent agents, and enzymes. A probe can also constitute radiolabelled PCR primers that are used to generate a radiolabelled amplicon. Labeling strategies for labeling nucleic acids and corresponding detection strategies can be found, e.g., in Haugland (1996) Handbook of Fluorescent Probes and Research Chemicals Sixth Edition by Molecular Probes, Inc. (Eugene, Oreg.); or Haugland (2001) Handbook of Fluorescent Probes and Research Chemicals Eighth Edition by Molecular Probes, Inc. (Eugene, Oreg.) (Available on CD ROM).

Amplification-Based Detection Methods

PCR, RT-PCR and LCR are in particularly broad use as amplification and amplification-detection methods for amplifying nucleic acids of interest (e.g., those comprising marker loci), facilitating detection of the markers. Details regarding the use of these and other amplification methods can be found in any of a variety of standard texts, including, e.g., Sambrook, Ausubel, Berger and Croy, herein. Many available biology texts also have extended discussions regarding PCR and related amplification methods. One of skill will appreciate that essentially any RNA can be converted into a double stranded DNA suitable for restriction digestion, PCR expansion and sequencing using reverse transcriptase and a polymerase (“Reverse Transcription-PCR, or “RT-PCR”). See also, Ausubel, Sambrook and Berger, above.

Real Time Amplification/Detection Methods

In one aspect, real time PCR or LCR is performed on the amplification mixtures described herein, e.g., using molecular beacons or TaqMan™ probes. A molecular beacon (MB) is an oligonucleotide or PNA which, under appropriate hybridization conditions, self-hybridizes to form a stem and loop structure. The MB has a label and a quencher at the termini of the oligonucleotide or PNA; thus, under conditions that permit intra-molecular hybridization, the label is typically quenched (or at least altered in its fluorescence) by the quencher. Under conditions where the MB does not display intra-molecular hybridization (e.g., when bound to a target nucleic acid, e.g., to a region of an amplicon during amplification), the MB label is unquenched. Details regarding standard methods of making and using MBs are well established in the literature and MBs are available from a number of commercial reagent sources. See also, e.g., Leone et al. (1995) “Molecular beacon probes combined with amplification by NASBA enable homogenous real-time detection of RNA.” Nucleic Acids Res. 26:2150-2155; Tyagi and Kramer (1996) “Molecular beacons: probes that fluoresce upon hybridization” Nature Biotechnology 14:303-308; Blok and Kramer (1997) “Amplifiable hybridization probes containing a molecular switch” Mol Cell Probes 11:187-194; Hsuih et al. (1997) “Novel, ligation-dependent PCR assay for detection of hepatitis C in serum” J Clin Microbiol 34:501-507; Kostrikis et al. (1998) “Molecular beacons: spectral genotyping of human alleles” Science 279:1228-1229; Sokol et al. (1998) “Real time detection of DNA:RNA hybridization in living cells” Proc. Natl. Acad. Sci. U.S.A. 95:11538-11543; Tyagi et al. (1998) “Multicolor molecular beacons for allele discrimination” Nature Biotechnology 16:49-53; Bonnet et al. (1999) “Thermodynamic basis of the chemical specificity of structured DNA probes” Proc. Natl. Acad. Sci. U.S.A. 96:6171-6176; Fang et al. (1999) “Designing a novel molecular beacon for surface-immobilized DNA hybridization studies” J. Am. Chem. Soc. 121:2921-2922; Marras et al. (1999) “Multiplex detection of single-nucleotide variation using molecular beacons” Genet. Anal. Biomol. Eng. 14:151-156; and Vet et al. (1999) “Multiplex detection of four pathogenic retroviruses using molecular beacons” Proc. Natl. Acad. Sci. U.S.A. 96:6394-6399. Additional details regarding MB construction and use is found in the patent literature, e.g., U.S. Pat. No. 5,925,517 (Jul. 20, 1999) to Tyagi et al. entitled “Detectably labeled dual conformation oligonucleotide probes, assays and kits;” U.S. Pat. No. 6,150,097 to Tyagi et al (Nov. 21, 2000) entitled “Nucleic acid detection probes having non-FRET fluorescence quenching and kits and assays including such probes” and U.S. Pat. No. 6,037,130 to Tyagi et al (Mar. 14, 2000), entitled “Wavelength-shifting probes and primers and their use in assays and kits.”

PCR detection and quantification using dual-labeled fluorogenic oligonucleotide probes, commonly referred to as “TaqMan™” probes, can also be performed according to the present invention. These probes are composed of short (e.g., 20-25 base) oligodeoxynucleotides that are labeled with two different fluorescent dyes. On the 5′ terminus of each probe is a reporter dye, and on the 3′ terminus of each probe a quenching dye is found. The oligonucleotide probe sequence is complementary to an internal target sequence present in a PCR amplicon. When the probe is intact, energy transfer occurs between the two fluorophores and emission from the reporter is quenched by the quencher by FRET. During the extension phase of PCR, the probe is cleaved by 5′ nuclease activity of the polymerase used in the reaction, thereby releasing the reporter from the oligonucleotide-quencher and producing an increase in reporter emission intensity. Accordingly, TaqMan™ probes are oligonucleotides that have a label and a quencher, where the label is released during amplification by the exonuclease action of the polymerase used in amplification. This provides a real time measure of amplification during synthesis. A variety of TaqMan™ reagents are commercially available, e.g., from Applied Biosystems (Division Headquarters in Foster City, Calif.) as well as from a variety of specialty vendors such as Biosearch Technologies (e.g., black hole quencher probes).

Additional Details Regarding Amplified Variable Sequences, SSR, AFLP ASH, SNPs and Isozyme Markers

Amplified variable sequences refer to amplified sequences of the plant genome which exhibit high nucleic acid residue variability between members of the same species. All organisms have variable genomic sequences and each organism (with the exception of a clone) has a different set of variable sequences. Once identified, the presence of specific variable sequence can be used to predict phenotypic traits. Preferably, DNA from the plant serves as a template for amplification with primers that flank a variable sequence of DNA. The variable sequence is amplified and then sequenced.

Alternatively, self-sustained sequence replication can be used to identify genetic markers. Self-sustained sequence replication refers to a method of nucleic acid amplification using target nucleic acid sequences which are replicated exponentially in vitro under substantially isothermal conditions by using three enzymatic activities involved in retroviral replication: (1) reverse transcriptase, (2) Rnase H, and (3) a DNA-dependent RNA polymerase (Guatelli et al. (1990) Proc Natl Acad Sci USA 87:1874). By mimicking the retroviral strategy of RNA replication by means of cDNA intermediates, this reaction accumulates cDNA and RNA copies of the original target.

Amplified fragment length polymophisms (AFLP) can also be used as genetic markers (Vos et al. (1995) Nucl Acids Res 23:4407). The phrase “amplified fragment length polymorphism” refers to selected restriction fragments which are amplified before or after cleavage by a restriction endonuclease. The amplification step allows easier detection of specific restriction fragments. AFLP allows the detection large numbers of polymorphic markers and has been used for genetic mapping of plants (Becker et al. (1995) Mol Gen Genet. 249:65; and Meksem et al. (1995) Mol Gen Genet 249:74).

Allele-specific hybridization (ASH) can be used to identify the genetic markers of the invention. ASH technology is based on the stable annealing of a short, single-stranded, oligonucleotide probe to a completely complementary single-strand target nucleic acid. Detection is via an isotopic or non-isotopic label attached to the probe.

For each polymorphism, two or more different ASH probes are designed to have identical DNA sequences except at the polymorphic nucleotides. Each probe will have exact homology with one allele sequence so that the range of probes can distinguish all the known alternative allele sequences. Each probe is hybridized to the target DNA. With appropriate probe design and hybridization conditions, a single-base mismatch between the probe and target DNA will prevent hybridization. In this manner, only one of the alternative probes will hybridize to a target sample that is homozygous or homogenous for an allele. Samples that are heterozygous or heterogeneous for two alleles will hybridize to both of two alternative probes.

ASH markers are used as dominant markers where the presence or absence of only one allele is determined from hybridization or lack of hybridization by only one probe. The alternative allele may be inferred from the lack of hybridization. ASH probe and target molecules are optionally RNA or DNA; the target molecules are any length of nucleotides beyond the sequence that is complementary to the probe; the probe is designed to hybridize with either strand of a DNA target; the probe ranges in size to conform to variously stringent hybridization conditions, etc.

PCR allows the target sequence for ASH to be amplified from low concentrations of nucleic acid in relatively small volumes. Otherwise, the target sequence from genomic DNA is digested with a restriction endonuclease and size separated by gel electrophoresis. Hybridizations typically occur with the target sequence bound to the surface of a membrane or, as described in U.S. Pat. No. 5,468,613, the ASH probe sequence may be bound to a membrane.

In one embodiment, ASH data are typically obtained by amplifying nucleic acid fragments (amplicons) from genomic DNA using PCR, transferring the amplicon target DNA to a membrane in a dot-blot format, hybridizing a labeled oligonucleotide probe to the amplicon target, and observing the hybridization dots by autoradiography.

Single nucleotide polymorphisms (SNP) are markers that consist of a shared sequence differentiated on the basis of a single nucleotide. In one embodiment, this distinction is detected by differential migration patterns of an amplicon comprising the SNP on e.g., an acrylamide gel. However, alternative modes of detection, such as hybridization, e.g., ASH, or RFLP analysis are also appropriate.

Detection of Markers for Positional Cloning

In some embodiments, a nucleic acid probe is used to detect a nucleic acid that comprises a marker sequence. Such probes can be used, for example, in positional cloning to isolate nucleotide sequences (e.g., CHI like fatty acid binding protein genes) linked to the marker nucleotide sequence. It is not intended that the nucleic acid probes of the invention be limited to any particular size. In some embodiments, nucleic acid probe is at least 20 nucleotides in length, or alternatively, at least 50 nucleotides in length, or alternatively, at least 100 nucleotides in length, or alternatively, at least 200 nucleotides in length.

A hybridized probe is detected using, autoradiography, fluorography or other similar detection techniques depending on the label to be detected. Examples of specific hybridization protocols are widely available in the art, see, e.g., Berger, Sambrook, and Ausubel, all herein.

Additional Details Regarding Sequence Variations

A number of particular CHI like fatty acid binding polypeptides and coding nucleic acids are described herein by sequence (See, e.g., Examples 1 and 2 and the Figures herein). These polypeptides and coding nucleic acids can be modified, e.g., by mutation as described herein, or simply by artificial synthesis of a desired variant. Several types of example variants are described below.

Silent Variations

Due to the degeneracy of the genetic code, any of a variety of nucleic acids sequences encoding polypeptides of the invention are optionally produced, some which can bear various levels of sequence identity to the CHI like fatty acid binding protein nucleic acids in the Examples below. The following provides a typical codon table specifying the genetic code, found in many biology and biochemistry texts.

TABLE 1 Codon Table Amino acids Codon Alanine Ala A GCA GCC GCG GCU Cysteine Cys C UGC UGU Aspartic acid Asp D GAC GAU Glutamic acid Glu E GAA GAG Phenylalanine Phe F UUC UUU Glycine Gly G GGA GGC GGG GGU Histidine His H CAC CAU Isoleucine Ile I AUA AUC AUU Lysine Lys K AAA AAG Leucine Leu L UUA UUG CUA CUC CUG CUU Methionine Met M AUG Asparagine Asn N AAC AAU Proline Pro P CCA CCC CCG CCU Glutamine Gln Q CAA CAG Arginine Arg R AGA AGG CGA CGC CGG CGU Serine Ser S AGC AGU UCA UCC UCG UCU Threonine Thr T ACA ACC ACG ACU Valine Val V GUA GUC GUG GUU Tryptophan Trp W UGG Tyrosine Tyr Y UAC UAU

The codon table shows that many amino acids are encoded by more than one codon. For example, the codons AGA, AGG, CGA, CGC, CGG, and CGU all encode the amino acid arginine. Thus, at every position in the nucleic acids of the invention where an arginine is specified by a codon, the codon can be altered to any of the corresponding codons described above without altering the encoded polypeptide. It is understood that U in an RNA sequence corresponds to T in a DNA sequence.

Such “silent variations” are one species of “conservatively modified variations”, discussed below. One of skill will recognize that each codon in a nucleic acid (except ATG, which is ordinarily the only codon for methionine) can be modified by standard techniques to encode a functionally identical polypeptide. Accordingly, each silent variation of a nucleic acid which encodes a polypeptide is implicit in any described sequence. The invention, therefore, explicitly provides each and every possible variation of a nucleic acid sequence encoding a polypeptide of the invention that could be made by selecting combinations based on possible codon choices. These combinations are made in accordance with the standard triplet genetic code (e.g., as set forth in Table 1, or as is commonly available in the art) as applied to the nucleic acid sequence encoding a polypeptide of the invention. All such variations of every nucleic acid herein are specifically provided and described by consideration of the sequence in combination with the genetic code. One of skill is fully able to make these silent substitutions using the methods herein.

Conservative Variations

“Conservatively modified variations” or, simply, “conservative variations” of a particular nucleic acid sequence or polypeptide are those which encode identical or essentially identical amino acid sequences. One of skill will recognize that individual substitutions, deletions or additions which alter, add or delete a single amino acid or a small percentage of amino acids (typically less than 5%, more typically less than 4%, 2% or 1%) in an encoded sequence are “conservatively modified variations” where the alterations result in the deletion of an amino acid, addition of an amino acid, or substitution of an amino acid with a chemically similar amino acid.

Conservative substitution tables providing functionally similar amino acids are well known in the art. Table 2 sets forth six groups which contain amino acids that are “conservative substitutions” for one another.

TABLE 2 Conservative Substitution Groups 1 Alanine (A) Serine (S) Threonine (T) 2 Aspartic acid (D) Glutamic acid (E) 3 Asparagine (N) Glutamine (Q) 4 Arginine (R) Lysine (K) 5 Isoleucine (I) Leucine (L) Methionine (M) Valine (V) 6 Phenylalanine (F) Tyrosine (Y) Tryptophan (W)

Thus, “conservatively substituted variations” of a listed polypeptide sequence of the present invention include substitutions of a small percentage, typically less than 5%, more typically less than 2% or 1%, of the amino acids of the polypeptide sequence, with a conservatively selected amino acid of the same conservative substitution group.

Finally, the addition or deletion of sequences which do not alter the encoded activity of a nucleic acid molecule, such as the addition or deletion of a non-functional sequence, is a conservative variation of the basic nucleic acid or polypeptide.

One of skill will appreciate that many conservative variations of the nucleic acid constructs which are disclosed yield a functionally identical construct. For example, as discussed above, owing to the degeneracy of the genetic code, “silent substitutions” (i.e., substitutions in a nucleic acid sequence which do not result in an alteration in an encoded polypeptide) are an implied feature of every nucleic acid sequence which encodes an amino acid. Similarly, “conservative amino acid substitutions,” in one or a few amino acids in an amino acid sequence are substituted with different amino acids with highly similar properties, are also readily identified as being highly similar to a disclosed construct. Such conservative variations of each disclosed sequence are a feature of the present invention.

Antibodies

In another aspect, antibodies to CHI like fatty acid binding polypeptides can be generated using methods that are well known. The antibodies can be utilized for detecting and/or purifying polypeptides e.g., in situ to monitor localization of the polypeptide, or simply for polypeptide detection in a biological sample of interest. Antibodies can optionally discriminate CHI like fatty acid binding polypeptide homologs. Antibodies can also, in some cases, be used to block function of CHI like fatty acid binding polypeptides, in vivo, in situ or in vitro (e.g., by binding to the fatty acid binding site on the protein). As used herein, the term “antibody” includes, but is not limited to, polyclonal antibodies, monoclonal antibodies, humanized or chimeric antibodies and biologically functional antibody fragments, which are those fragments sufficient for binding of the antibody fragment to the protein.

For the production of antibodies to a polypeptide encoded by one of the disclosed sequences or conservative variant or fragment thereof, various host animals may be immunized by injection with the polypeptide, or a portion thereof. Such host animals may include, but are not limited to, rabbits, mice and rats, to name but a few. Various adjuvants may be used to enhance the immunological response, depending on the host species, including, but not limited to, Freund's (complete and incomplete), mineral gels such as aluminum hydroxide, surface active substances such as lysolecithin, pluronic polyols, polyanions, peptides, oil emulsions, keyhole limpet hemocyanin, dinitrophenol, and potentially useful human adjuvants such as BCG (bacille Calmette-Guerin) and Corynebacterium parvum.

Polyclonal antibodies are heterogeneous populations of antibody molecules derived from the sera of animals immunized with an antigen, such as target gene product, or an antigenic functional derivative thereof. For the production of polyclonal antibodies, host animals, such as those described above, may be immunized by injection with the encoded protein, or a portion thereof, supplemented with adjuvants as also described above.

Monoclonal antibodies (mAbs), which are homogeneous populations of antibodies to a particular antigen, may be obtained by any technique which provides for the production of antibody molecules by continuous cell lines in culture. These include, but are not limited to, the hybridoma technique of Kohler and Milstein (Nature 256:495-497, 1975; and U.S. Pat. No. 4,376,110), the human B-cell hybridoma technique (Kosbor et al., Immunology Today 4:72, 1983; Cole et al., Proc. Nat'l. Acad. Sci. USA 80:2026-2030, 1983), and the EBV-hybridoma technique (Cole et al., Monoclonal Antibodies and Cancer Therapy, Alan R. Liss, Inc., pp. 77-96, 1985). Such antibodies may be of any immunoglobulin class, including IgG, IgM, IgE, IgA, IgD, and any subclass thereof. The hybridoma producing the mAb of this invention may be cultivated in vitro or in vivo. Production of high titers of mAbs in vivo makes this the presently preferred method of production.

In addition, techniques developed for the production of “chimeric antibodies” (Morrison et al., Proc. Nat'l. Acad. Sci. USA 81:6851-6855, 1984; Neuberger et al., Nature 312:604-608, 1984; Takeda et al., Nature 314:452-454, 1985) by splicing the genes from a mouse antibody molecule of appropriate antigen specificity, together with genes from a human antibody molecule of appropriate biological activity, can be used. A chimeric antibody is a molecule in which different portions are derived from different animal species, such as those having a variable or hypervariable region derived from a murine mAb and a human immunoglobulin constant region.

Alternatively, techniques described for the production of single-chain antibodies (U.S. Pat. No. 4,946,778; Bird, Science 242:423-426, 1988; Huston et al., Proc. Nat'l. Acad. Sci. USA 85:5879-5883, 1988; and Ward et al., Nature 334:544-546, 1989) can be adapted to produce differentially expressed gene-single chain antibodies. Single chain antibodies are formed by linking the heavy and light chain fragments of the Fv region via an amino acid bridge, resulting in a single-chain polypeptide.

In one aspect, techniques useful for the production of “humanized antibodies” can be adapted to produce antibodies to the proteins, fragments or derivatives thereof. Such techniques are disclosed in U.S. Pat. Nos. 5,932,448; 5,693,762; 5,693,761; 5,585,089; 5,530,101; 5,569,825; 5,625,126; 5,633,425; 5,789,650; 5,661,016; and 5,770,429.

Antibody fragments which recognize specific epitopes may be generated by known techniques. For example, such fragments include, but are not limited to, the F(ab′)₂ fragments, which can be produced by pepsin digestion of the antibody molecule, and the Fab fragments, which can be generated by reducing the disulfide bridges of the F(ab′)₂ fragments. Alternatively, Fab expression libraries may be constructed (Huse et al., Science 246:1275-1281, 1989) to allow rapid and easy identification of monoclonal Fab fragments with the desired specificity.

The protocols for detecting and measuring the expression of the described polypeptides herein, using the above mentioned antibodies, are well known in the art. Such methods include, but are not limited to, dot blotting, western blotting, competitive and noncompetitive protein binding assays, enzyme-linked immunosorbant assays (ELISA), immunohistochemistry, fluorescence-activated cell sorting (FACS), and others commonly used and widely described in scientific and patent literature, and many employed commercially.

One method, for ease of detection, is the sandwich ELISA, of which a number of variations exist, all of which are intended to be encompassed by the present invention. For example, in a typical forward assay, unlabeled antibody is immobilized on a solid substrate and the sample to be tested is brought into contact with the bound molecule and incubated for a period of time sufficient to allow formation of an antibody-antigen binary complex. At this point, a second antibody, labeled with a reporter molecule capable of inducing a detectable signal, is then added and incubated, allowing time sufficient for the formation of a ternary complex of antibody-antigen-labeled antibody. Any unreacted material is washed away, and the presence of the antigen is determined by observation of a signal, or may be quantified by comparing with a control sample containing known amounts of antigen. Variations on the forward assay include the simultaneous assay, in which both sample and antibody are added simultaneously to the bound antibody, or a reverse assay, in which the labeled antibody and sample to be tested are first combined, incubated and added to the unlabeled surface bound antibody. These techniques are well known to those skilled in the art, and the possibility of minor variations will be readily apparent. As used herein, “sandwich assay” is intended to encompass all variations on the basic two-site technique. For the immunoassays of the present invention, the only limiting factor is that the labeled antibody be an antibody which is specific for the protein expressed by the gene of interest.

The most commonly used reporter molecules in this type of assay are either enzymes, fluorophore- or radionuclide-containing molecules. In the case of an enzyme immunoassay, an enzyme is conjugated to the second antibody, usually by means of glutaraldehyde or periodate. As will be readily recognized, however, a wide variety of different ligation techniques exist which are well-known to the skilled artisan. Commonly used enzymes include horseradish peroxidase, glucose oxidase, beta-galactosidase and alkaline phosphatase, among others. The substrates to be used with the specific enzymes are generally chosen for the production, upon hydrolysis by the corresponding enzyme, of a detectable color change. For example, p-nitrophenyl phosphate is suitable for use with alkaline phosphatase conjugates; for peroxidase conjugates, 1,2-phenylenediamine or toluidine are commonly used. It is also possible to employ fluorogenic substrates, which yield a fluorescent product, rather than the chromogenic substrates noted above. A solution containing the appropriate substrate is then added to the tertiary complex. The substrate reacts with the enzyme linked to the second antibody, giving a qualitative visual signal, which may be further quantified, usually spectrophotometrically.

Alternately, fluorescent compounds, such as fluorescein and rhodamine, can be chemically coupled to antibodies without altering their binding capacity. When activated by illumination with light of a particular wavelength, the fluorochrome-labeled antibody absorbs the light energy, inducing a state of excitability in the molecule, followed by emission of the light at a characteristic longer wavelength. The emission appears as a characteristic color visually detectable with a light microscope. Immunofluorescence and EIA techniques are both very well established in the art and are particularly preferred for the present method. However, other reporter molecules, such as radioisotopes, chemiluminescent or bioluminescent molecules may also be employed. It will be readily apparent to the skilled artisan how to vary the procedure to suit the required use.

EXAMPLES

The following examples are illustrative and not limiting. One of skill will recognize a variety of parameters that can be modified to achieve essentially similar results.

Example 1 A Sub-Family of Chalcone Isomerase Like Genes, Encoding Proteins that Bind Fatty Acids (FA) with High Affinity

The current invention describes a novel sub-family of chalcone isomerase like genes, the protein products of which bind fatty acids (FA) with high affinity. Binding was established first by the elucidation of a high resolution crystal structure of one protein expressed and purified from E. coli (At3g63170, referred to as At279) and confirmed by HPLC-MS analyses of extractions of protein samples of At279 and a close homolog (At1g53520, referred to as At287). These proteins have a three-dimensional fold similar to chalcone isomerase (At3g55120, referred to as AtCHI) but, as compared to chalcone isomerase, lack key catalytic residues known to catalyze the formation of flavanones from chalcone substrates.

These members of the chalcone isomerase like gene family are widely distributed in plants, various bacteria, fungi and some eukaryotic organisms. Bioinformatic analyses of the two genes in question strongly suggests that the nuclear encoded proteins are localized in the chloroplast, where the majority of plant fatty acid biosynthesis occurs. Moreover, we hypothesize that these two proteins are directly involved in the transport of free fatty acids from the inner thylakoid membrane to the outer envelope of the plastid where they are reactivated to acyl-CoAs for utilization in cytosolic glycerolipid synthesis.

The metabolic engineering of plant fatty acid biosynthesis (FAS) has progressed rapidly in the past 10 years and has led to the commercialization of several modified oilseed crops. However, it has been difficult to engineer plants with increased flux through the biosynthetic pathways (1, 2). Our discovery of a new FA binding protein family and their future over-expression in FA bio-engineered plants may improve the plant FA content by allowing natural FA to be transported more efficiently. The search for these transporters has been intense but was previously unresolved (3). Moreover, our knowledge of the detailed binding mode of natural FAs, as well as synthetic FAs, provides the necessary tools for structure-based engineering of modified FA transporters.

Materials and Methods

Cloning, expression and purification of At3g63170 (At279) and At1g53520 (At287): Arabidopsis thaliana At3g63170 (At279) and At1g53520 (At287) genes were subcloned into the pHIS8 Escherichia coli expression vector derived from pET28a (+). For crystallization purpose, constructs of At279 and At287 lacking the transit peptide sequence found at the N-terminal region of the protein (˜50 amino acids) were also created. Transformed E. coli BL21 (DE3) cells were incubated with shaking at 37° C. in Terrific broth containing 50 μg/ml kanamycin until A(600 nm)=1.0. Protein expression was induced with 0.5 mM isopropyl 1-thio-β-galactopyranoside, and the cultures were incubated with shaking at 22° C. for an additional 6 h. Cells were harvested by centrifugation at 9,000×g and cell pellets re-suspended in lysis buffer (500 mM NaCl, 50 mM Tris-HCl (pH 8.0), 20 mM imidazole, 10% (v/v) glycerol 1% (v/v) Tween 20, 10 mM β-mercaptoethanol) supplemented with 1 mg/ml lysozyme. Following sonication and centrifugation of the lysed cell debris at 100,000×g, the supernatant was passed over a Ni2+-NTA column (Qiagen, Valencia, Calif.) equilibrated in lysis buffer, washed with 10 bed volumes of wash buffer (500 mM NaCl, 50 mM Tris-HCl (pH 8.0), 20 mM imidazole, 10 mM β-mercaptoethanol), and the His-tagged protein eluted with 10 bed volumes of elution buffer (500 mM NaCl, 50 mM Tris-HCl (pH 8.0), 250 mM imidazole, 10 mM β-mercaptoethanol). The N-terminal His tag was cleaved by thrombin digestion during a 24-h dialysis against digestion buffer (500 mM NaCl, 50 mM Tris (pH 8.0), 10 mM β-mercaptoethanol) at 4° C. Cleaved protein was isolated by running the dialyzed sample over another Ni2+-NTA column equilibrated in digestion buffer to remove the His tag and uncleaved protein, followed by a benzamidine-Sepharose column to remove thrombin. A Superdex S75 gel filtration column (Amersham Biosciences) equilibrated in gel filtration buffer (500 mM NaCl, 25 mM HEPES (pH 7.5), 2 mM dithiothreitol (DTT)) was utilized to isolate homogeneous At279 and A287. Peak fractions were collected and dialyzed against crystallization storage buffer (100 mM NaCl, 25 mM HEPES (pH 7.5), 2 mM DTT). The resulting samples were subjected to SDS-PAGE and judged to be >95% pure based upon Coomassie staining. At279 and At287 were subsequently concentrated to 10-15 mg/ml and stored at −80° C.

AT279 Crystal Structure

Crystallization and Data Collection of At3g63170 Protein Crystals (At279)

Crystals of the heterologously expressed At279 C-terminal construct (residues 77 to 279) were obtained by vapor diffusion in 2 μl hanging drops incubated at 4° C. and consisting of a 1:1 mixture of protein and crystallization buffer. The crystallization buffer contained 19% (w/v) PEG 3350, 0.3 M KCl, 2 mM DTT and 100 mM TAPS buffer at pH 8.5. Prior to freezing in liquid nitrogen, native crystals were passed through a cryogenic buffer identical to the crystallization buffer except for the use of 21% (w/v) PEG 3350 and the inclusion of 20% (v/v) ethylene glycol. For heavy atom derivatization, native At279 crystals were soaked overnight in crystallization buffer differing from the crystallization solution due to an increased PEG 3350 concentration (21% (w/v)) and the inclusion of 1 mM K2PtCl4 prior to cryogenic freezing as before. A multi-wavelength anomalous dispersion (MAD) data set was collected at the Pt edge on a K2PtCl4 derivative crystal at the Stanford Synchrotron Radiation Laboratory (SSRL) on beam line BL1-5. Data were processed with HKL2000 and reduced to a unique set of indexed intensities to a resolution of 2.6 Å. A single-wavelength native data set was collected at SSRL and processed with HKL2000 to a resolution of 1.9 Å. At279 crystals belong to the P2(1)2(1)2(1) space group, with average unit cell dimensions of a=56.44 Å, b=56.96 Å, c=140.37 Å, α=β=γ=90°.

Structure Determination and Coordinate Refinement of At3g63170 Protein (At279)

The At279 structure was solved from the 2.6-Å platinum derivative data set. Experimental multiple wavelength anomalous dispersion phases were obtained using SOLVE (4). The experimental electron density maps were improved by bulk solvent density modification and automated building with RESOLVE (4). Additional rounds of building and refinement were carried out with 0 (5) and CNS (6), respectively, and then final rounds with REFMAC5 (7). Native At279 was solved by molecular replacement with MOLREP (8), part of the CCP4 Suite (9).

AT287 Crystal Structure

Crystallization and Data Collection of At1g153520 Protein Crystals (At287)

Crystals of the heterologously expressed At287 C-terminal construct (residues 90 to 287) were obtained by vapor diffusion in 2 μl hanging drops at 4° C. consisting of a 1:1 mixture of protein and crystallization buffer. The crystallization buffer contained 9% (w/v) PEG 8000, 0.2 M calcium acetate, 2 mM DTT and 100 mM PIPES buffer at pH 6.5. Prior to freezing in liquid nitrogen, crystals were passed through a cryogenic buffer identical to the crystallization buffer except for the use of 11% (w/v) PEG 8000 and the inclusion of 20% (v/v) ethylene glycol. A data set was collected at the Advanced Light Source at Berkeley (ALS) on beam line 8.2.2 and processed using XDS to a resolution of 2 Å (10). At287 crystals belong to the P4(2)2(1)2 space group, with average unit cell dimensions of a=b=108.46 Å, c=51.31 Å, α=β=γ=90°.

Structure Determination and Coordinate Refinement of At287 Protein

The At287 structure was solved by molecular replacement using Phaser, part of the CCP4 suite. The previously described 1.9 Å At279 structure was used as a search model. The initial molecular replacement model was manually adjusted in COOT and refined with REFMAC5 (7). Structure figures were prepared with PyMol (11).

LC-MS Analysis of Fatty Acids (FA) Bound to Purified At279 and At287 Proteins.

At279 and At287 proteins were purified to homogeneity as described above. Ice-cold HPLC grade ethanol (600 μl) was added to the proteins (150 μl protein sample at 10 mg/ml previously dialyzed against 20 mM ammonium bicarbonate). The samples were vortexed and incubated at −20° C. for 3 days. For LC-MS analysis, the samples were centrifuged, and the supernatant containing the FAs was removed and placed in a new glass vial. The solvent was evaporated at 25° C., and the remaining residue resuspended in 200 μl propanol. The extracts were analyzed by liquid chromatography (LC) using an Agilent 1100 HPLC employing a Gemini reversed-phase C18 column (4.6×150 mm, 5μ) running at a flow rate of 1 ml/min, and coupled to an electrospray ionization (ESI) XCT ion trap mass spectrometer (Agilent) operated in the negative-ion mode employing a continual introduction of a 20 mM ammonium acetate solution flowing at 100 μl/min. A linear gradient of acetonitrile (30-100% v/v) in 25 mM ammonium bicarbonate, pH 8, was used. The negative ion-ESI mass spectra of FA standards were as follows: Lauric acid (C12:0) (m/z)=198.7 ([M-H]−), Myristic acid (C14:0) (m/z)=226.9 ([M-H]−), Palmitic acid (C16:0) (m/z)=254.9 ([M-H]−) and Stearic acid (C18:0) (m/z)=282.9 ([M-H]−). At279 and At287 extracts clearly showed the presence of saturated FA (C12:0, C14:0, C16:0 and C18:0) as well as unsaturated FA (C16:1 (m/z)=253.1 ([M-H]−) and C18:1 (m/z)=281.4 ([M-H]−) (see FIG. 3). Purified AtCHI protein was also analyzed for its FAs content; no trace of FAs was detected using the same method described above providing an appropriate negative control.

Results

Discovery and Bioinformatics Analyses of these New Fatty Acids Binding Proteins.

We discovered the genes and encoded proteins for these two naturally occurring FA binding proteins using bioinformatic analyses of available genomic sequencing data from the plant Arabidopsis thaliana. These two homologs, referred to as At279 (At3g63170) and At287 (At1g53520), named based upon their amino acid length, are small proteins located on different chromosomes. At279 and At287, as well as At396 (TAIR accession number At2g26310; see also accession number Q58G09 in the UniProt database) form a novel sub-family of CHI like proteins in the Arabidopsis chalcone isomerase (CHI) family. The CHI family contains 6-members in Arabidopsis ranging from 209 to 396 amino acids in length, and exhibiting 25 to 60% amino acid sequence identity (FIG. 1). In plants, these proteins are ubiquitous and often abundantly expressed. The last 200 C-terminal amino acids of At279 and At287 (as well as At396) share homology to our previously solved Medicago sativa L. (Alfalfa) chalcone isomerase crystal structure; however, they lack key residues previously identified in our laboratory that are critically involved in the near diffusion controlled (“Perfect Enzyme”) and stereospecific conversion of chalcone into (2S)-naringenin (12). Within the first 80-90 N-terminal amino acid residues, a plastid signal sequence is found. At279 was annotated as localized in the plastid stroma by the plastid proteome database (http://ppdb(dot)tc(dot)comell(dot)edu/ and http://www(dot)plastid(dot)msu(dot)edu/), as expected based upon the sequence of their N-terminal extensions relative to authentic CHI. We are currently experimentally analyzing the locale of these two FA binding proteins and other sequence relatives using GFP fusion technology in transgenic Arabidopsis thaliana plants.

Three Dimensional Structure of At279 and At287

Arabidopsis thaliana At279 and At287 were over-expressed in E. coli, purified to homogeneity and crystallized (see Materials and Methods). We solved the x-ray crystal structure of At279 and At287, as well as the crystal structure of Arabidopsis thaliana CHI (At3g55120, referred to as AtCHI) for comparative purposes. The structure of At279 recently completed confirms conservation of the unique open-faced β-sandwich fold of CHI (13). A large beta-sheet and a layer of alpha helices comprise the core structure with three short beta-strands on the opposite side of the large beta-sheet (FIG. 2A-B). However, a highly divergent (shape and amino acid distribution) active site cavity as suggested by sequence alignments between CHI and these FA binding proteins is clearly present (FIG. 1). Active site residues, which are conserved in all known CHIs, include Thr 59, Tyr 117, Asn 124, and Thr/Ser 201 (Arabidopsis CHI sequence annotation), and participate in the hydrogen bond network that mediates CHI substrate recognition and stereospecific flavanone formation. Moreover, a final invariant residue essential for catalysis, Arg 47, acts as an electrostatic component for substrate binding and orientation and also stabilizes the transition state of the cyclization reaction. Alteration of the Alfalfa CHI residue corresponding to this Arg (Arg 36) by site-directed mutation obliterates CHI activity (14). As is apparent from the alignment depicted in FIG. 1, At279 and At287 proteins contain Arg 47 but lack all of the hydrogen-bonding residues found in catalytically active CHIs. In fact, Thr 59 in AtCHI is replaced by Tyr 116 (in At279) or Tyr 126 (in At287), Tyr 117 in AtCHI is replaced by Val 176 (in At279) or Phe 183 (in At287), Asn 124 in AtCHI is replaced by Ser 183 (in At279) or Ala 190 (in At287), and Ser 201 in AtCHI is replaced by Leu 254 (in At279) or Val 263 (in At287).

During the very first stages of structure elucidation using x-ray crystallography, we observed a very well ordered and clearly defined small molecule bound in a cavity partially overlapping with the originally identified CHI active site. This small molecule was clearly the fatty acid lauric acid (C12:0), likely derived from E. coli. The carboxylic acid group is nicely sequestered by electrostatic interactions with the absolutely conserved Arg and Tyr residues (Arg 103 and Tyr 116 in At279, Arg 114 and Tyr 126 in At287). The fatty acyl chain is bound in a new hydrophobic cavity formed in the CHI fold and distinct from the active site cavity of AtCHI.

LC-MS Analysis of FAs Bound to Purified At279 and At287 Proteins

LC-MS analysis of recombinantly prepared At279 and At287 confirmed that they bind an entire set of linear fatty acids representative of E. coli's saturated fatty acid (Lauric acid (C12:0) (m/z)=198.7 ([M-H]−), Myristic acid (C14:0) (m/z)=226.9 ([M-H]-), Palmitic acid (C16:0) (m/z)=254.9 ([M-H]−) and Stearic acid (C18:0) (m/z)=282.9 ([M-H]−)) as well as unsaturated FAs (C16:1 (m/z)=253.1 ([M-H]−) and C18:1 (m/z)=281.4 ([M-H]−) (FIG. 3). Identical analyses of AtCHI clearly possessing authentic CHI catalytic activity showed no such fatty acid binding activity (data not shown).

The discovery of this novel family of FA binding proteins in Arabidopsis using both protein x-ray crystallography and LC-MS analysis suggest that this Arabidopsis FA binding protein family may have considerable potential for improving the engineering of lipids in plants possibly using a structurally-guided approach to create novel variants using rational protein engineering. It is important to point out that homologs of these FA binding proteins are also found outside higher plants, for example in the unicellular algae Chlamydomonas, as well as in the eukaryotic slime mold Dictyostelium, suggesting an important role for these proteins in lipid metabolism and transport in other organisms.

REFERENCES

-   1. Thelen, J. J. & Ohlrogge, J. B. (2002) Metab Eng 4, 12-21. -   2. Broun, P., Gettner, S. & Somerville, C. (1999) Annu Rev Nutr 19,     197-216. -   3. Koo, A. J., Ohlrogge, J. B. & Pollard, M. (2004) J Biol Chem 279,     16101-10. -   4. Terwilliger, T. (2004) J Synchrotron Radiat 11, 49-52. -   5. Jones, T. A., Zou, J. Y., Cowan, S. W. & Kjeldgaard (1991) Acta     Crystallogr A 47 (Pt 2), 110-9. -   6. Brunger, A. T., Adams, P. D., Clore, G. M., DeLano, W. L., Gros,     P., Grosse-Kunstleve, R. W., Jiang, J. S., Kuszewski, J., Nilges,     M., Pannu, N. S., Read, R. J., Rice, L. M., Simonson, T. &     Warren, G. L. (1998) Acta Crystallogr D Biol Crystallogr 54 (Pt 5),     905-21. -   7. Vagin, A. A., Steiner, R. A., Lebedev, A. A., Potterton, L.,     McNicholas, S., Long, F. & Murshudov, G. N. (2004) Acta Crystallogr     D Biol Crystallogr 60, 2184-95. -   8. Vagin, A. A. & Isupov, M. N. (2001) Acta Crystallogr D Biol     Crystallogr 57, 1451-6. -   9. C.C.P.4 (1999) Acta cryst. d50, 760-763. -   10. Kabsch, W. (2001) XDS in International Tables for     Crystallography (Kluwer Academic Publisher, Dordrecht). -   11. DeLano, W. L. (2002) www(dot)pymol(dot)org. -   12. Jez, J. M. & Noel, J. P. (2000) J Biol Chem 275, 39640-6. -   13. Jez, J. M., Ferrer, J. L., Bowman, M. E., Austin, M. B.,     Schroder, J., Dixon, R. A. & Noel, J. P. (2001) J Ind Microbiol     Biotechnol 27, 393-8. -   14. Jez, J. M., Larsen, E., Pojer, F., Bowman, M. E. &     Noel, J. P. (2006) in preparation.

Example 2 WU-BLAST 2.0 Queries

WU-BLAST 2.0 queries were performed by TAIR in the Uniprot Plant Proteins database. For full BLAST options and parameters, refer to the BLAST Documentation at NCBI. The release of BLASTP was 2.0 MP-WashU [10 Apr. 2004] [linux24-i686-ILP32F64 2004-04-11T01:00:13]. Well-known references for the relevant algorithms and BLAST programs include Altschul et al. (1990) “Basic local alignment search tool,” J. Mol. Biol. 215:403-410; Gish et al. (1993) “Identification of protein coding regions by database similarity search,” Nature Genetics 3:266-72 and Gish and Warren (1994) unpublished information in the BLAST2 Documentation.

At279 was searched using TAIR as described, using a query sequence length of 279 letters, in the database: /home/patlibs/Uniprot Plant Proteins. Table 3 provides results of the search. Sequence alignments between At279 and any of the sequences below can be produced by TAIR using WU-BLAST 2.0, e.g., set to default parameters, and viewed with publicly available sequence alignment tools such as those provided by TAIR (similar searches can be run directly in UniProt or other available databases). Sequences below are obtained by providing the indicated sequence accession number (in parentheses) to the UniProt database (e.g., on the world wide web at pir(dot)uniprot(dot)org).

TABLE 3 Blast Results for At279 Smallest Sum High Probability Sequences producing High-scoring Segment Pairs: score P (N) N Q9M1X2_ARATH (Q9M1X2) Hypothetical protein F16M2_20 (Hypo . . . 1231  1.6e−125 1 Q6V7U9_LYCES (Q6V7U9) Putative chalcone isomerase - Lycop . . . 391 1.6e−36 1 Q69SP9_ORYSA (Q69SP9) Hypothetical protein OSJNBa0016O19 . . . 364 1.2e−33 1 Q6K7H0_ORYSA (Q6K7H0) Hypothetical protein OJ1293_A01.5 - . . . 360 3.1e−33 1 Q58G09_ARATH (Q58G09) Hypothetical protein - Arabidopsis . . . 300 7.1e−27 1 Q84RK2_ARATH (Q84RK2) Hypothetical protein At2g26310/T1D1 . . . 300 7.1e−27 1 Q84RK3_ARATH (Q84RK3) Hypothetical protein At2g26310/T1D1 . . . 300 7.1e−27 1 Q8GXU6_ARATH (Q8GXU6) Hypothetical protein At2g26310 - Ar . . . 300 7.1e−27 1 Q6YTV0_ORYSA (Q6YTV0) Hypothetical protein OJ1121_A05.15 . . . 258 2.0e−22 1 O64841_ARATH (O64841) Hypothetical protein At2g26310 - Ar . . . 112 6.9e−10 2 Q9ZWR1_CITSI (Q9ZWR1) Chalcone isomerase - Citrus sinensi . . . 128 1.2e−06 1 Q53B73_SOYBN (Q53B73) Putative chalcone isomerase 3 - Gly . . . 126 4.7e−06 1 Q8LFP0_ARATH (Q8LFP0) Chalcone isomerase, putative - Arab . . . 115 9.8e−05 1 Q4AE12_FRAAN (Q4AE12) Chalcone isomerase - Fragaria anana . . . 111 0.00018 1 Q84T92_ORYSA (Q84T92) Chalcone isomerase - Oryza sativa (. . . 108 0.00039 1 Q8S911_IPOBA (Q8S911) Chalcone isomerase - Ipomoea batata . . . 107 0.00057 1 Q4AE11_FRAAN (Q4AE11) Chalcone isomerase - Fragaria anana . . . 106 0.00071 1 Q9LRF1_IPOBA (Q9LRF1) Chalcone isomerase (Fragment) - Ipo . . . 105 0.00098 1 CFI_ELAUM (O65333) Chalcone--flavonone isomerase (EC 5.5 . . . 103 0.0019 1 Q8S3X1_ORYSA (Q8S3X1) Chalcone isomerase (EC 5.5.1.6) - O . . . 102 0.0020 1 CFI_MAIZE (Q08704) Chalcone--flavonone isomerase (EC 5.5 . . . 100 0.0034 1 CFI_IPOPU (O22604) Chalcone--flavonone isomerase (EC 5.5 . . . 99 0.0049 1 Q6EQW2_ORYSA (Q6EQW2) Chalcone isomerase-like - Oryza sat . . . 99 0.0067 1 Q9FLC7_ARATH (Q9FLC7) Similarity to chalcone-flavonone is . . . 94 0.013 1 Q8S3X0_HORVD (Q8S3X0) Chalcone isomerase (EC 5.5.1.6) - H . . . 95 0.013 1 Q8VZW3_ARATH (Q8VZW3) Hypothetical protein At5g05270 (Con . . . 94 0.013 1 CFI_RAPSA (O22651) Chalcone--flavonone isomerase (EC 5.5 . . . 94 0.020 1 Q53B72_SOYBN (Q53B72) Putative chalcone isomerase 4 - Gly . . . 88 0.066 1 CFI_PUELO (Q43056) Chalcone--flavonone isomerase (EC 5.5 . . . 87 0.10 1 Q8LKP9_SAUME (Q8LKP9) Chalcone isomerase - Saussurea medu . . . 87 0.11 1 Q8H0G1_LOTJA (Q8H0G1) Putative chalcone isomerase - Lotus . . . 86 0.12 1 CFI_VITVI (P51117) Chalcone--flavonone isomerase (EC 5.5 . . . 86 0.14 1 CFI_ARATH (P41088) Chalcone--flavonone isomerase (EC 5.5 . . . 85 0.19 1 Q53B71_SOYBN (Q53B71) Chalcone isomerase 4B (Fragment) - . . . 79 0.20 1 CHI_ARALP (Q9LKC3) Chalcone--flavonone isomerase (EC 5.5 . . . 84 0.24 1 Q8LGS3_ROSHC (Q8LGS3) Chalcone isomerase (Fragment) - Ros . . . 77 0.32 1 Q6QHK0_ALLCE (Q6QHK0) Chalcone isomerase - Allium cepa (O . . . 82 0.33 1 Q66VY8_ALLCE (Q66VY8) Chalcone isomerase - Allium cepa (O . . . 81 0.41 1 Q66VY9_ALLCE (Q66VY9) Chalcone isomerase - Allium cepa (O . . . 81 0.41 1 Q45QI7_CAMSI (Q45QI7) Chalcone isomerase - Camellia sinen . . . 78 0.70 1 Q5VMY4_ORYSA (Q5VMY4) Putative DNA topoisomerase I - Oryz . . . 84 0.81 1 CFI_CALCH (Q42663) Chalcone--flavonone isomerase (EC 5.5 . . . 76 0.88 1 Q3Y4F4_9LILI (Q3Y4F4) Chalcone isomerase - Canna generalis 73 0.99 1 Q9SSD8_ARATH (Q9SSD8) F18B13.3 protein - Arabidopsis thal . . . 80 0.991 1 Q9CA97_ARATH (Q9CA97) Hypothetical protein F19K16.9 - Ara . . . 80 0.993 1 Q33B68_ORYSA (Q33B68) Hypothetical protein - Oryza sativa . . . 53 0.996 1 Q39946_HELAN (Q39946) HAHB-6 (Fragment) - Helianthus annu . . . 51 0.9999 1 Q9LMH8_ARATH (Q9LMH8) T2D23.13 protein - Arabidopsis thal . . . 59 0.99993 1

Similarly, At287 was searched against UniProt using TAIR as described, using a query sequence length of 287 letters, in the database: /home/patlibs/Uniprot Plant Proteins. Table 4 provides results of the search. Sequence alignments between At287 and any of the sequences below are produced by WU-BLAST 2.0, e.g., set to default parameters and viewed with publicly available sequence alignment tools such as those provided by TAIR (similar searches can be run directly in UniProt or other available databases). Sequences below are obtained by providing the indicated sequence accession number (in parentheses) to the UniProt database (e.g., on the world wide web at pir(dot)uniprot(dot)org.

TABLE 4 Blast Results for At287 Smallest Sum High Probability Sequences producing High-scoring Segment Pairs: Score P(N) N Q9C8L2_ARATH (Q9C8L2) Chalcone isomerase, putative; 94270 . . . 1340  4.4e−137 1 Q8LFP0_ARATH (Q8LFP0) Chalcone isomerase, putative - Arab . . . 1331  4.0e−136 1 Q9LPG8_ARATH (Q9LPG8) T3F20.16 protein - Arabidopsis thal . . . 1217  4.8e−124 1 Q53B73_SOYBN (Q53B73) Putative chalcone isomerase 3 - Gly . . . 656 1.3e−64 1 Q6EQW2_ORYSA (Q6EQW2) Chalcone isomerase-like - Oryza sat . . . 390 2.1e−36 1 Q565D8_GENTR (Q565D8) Chalcone flavonone isomerase - Gent . . . 175 1.3e−13 1 Q8H0G1_LOTJA (Q8H0G1) Putative chalcone isomerase - Lotus . . . 167 1.2e−12 1 Q6BEH3_EUSGR (Q6BEH3) Chalcone isomerase - Eustoma grandi . . . 163 3.6e−12 1 Q53B75_SOYBN (Q53B75) Chalcone isomerase 1B1 (EC 5.5.1.6) . . . 162 2.8e−11 1 Q3Y4F3_9LILI (Q3Y4F3) Chalcone isomerase - Canna generalis 159 1.0e−10 1 Q4AE12_FRAAN (Q4AE12) Chalcone isomerase - Fragaria anana . . . 161 1.1e−10 1 Q3Y4F4_9LILI (Q3Y4F4) Chalcone isomerase - Canna generalis 158 1.5e−10 1 Q53B72_SOYBN (Q53B72) Putative chalcone isomerase 4 - Gly . . . 151 3.5e−10 1 Q53B70_SOYBN (Q53B70) Chalcone isomerase 1B2 (EC 5.5.1.6) . . . 155 4.5e−10 1 Q8LKP9_SAUME (Q8LKP9) Chalcone isomerase - Saussurea medu . . . 150 3.2e−09 1 Q9ZWR1_CITSI (Q9ZWR1) Chalcone isomerase - Citrus sinensi . . . 148 4.1e−09 1 Q8S911_IPOBA (Q8S911) Chalcone isomerase - Ipomoea batata . . . 149 6.2e−09 1 Q33DL3_TOBAC (Q33DL3) Chalcone isomerase - Nicotiana taba . . . 149 6.3e−09 1 Q4AE11_FRAAN (Q4AE11) Chalcone isomerase - Fragaria anana . . . 148 7.0e−09 1 Q45QI7_CAMSI (Q45QI7) Chalcone isomerase - Camellia sinen . . . 147 7.5e−09 1 CFI_DIACA (Q43754) Chalcone--flavonone isomerase (EC 5.5 . . . 144 1.4e−08 1 CFI_IPOPU (O22604) Chalcone--flavonone isomerase (EC 5.5 . . . 146 1.4e−08 1 Q9LRF1_IPOBA (Q9LRF1) Chalcone isomerase (Fragment) - Ipo . . . 145 1.9e−08 1 Q53B74_SOYBN (Q53B74) Chalcone isomerase 2 (EC 5.5.1.6) - . . . 142 3.1e−08 1 Q8S3X0_HORVD (Q8S3X0) Chalcone isomerase (EC 5.5.1.6) - H . . . 142 3.6e−08 1 Q42925_MALSP (Q42925) Chalcone isomerase (EC 5.5.1.6) (Fr . . . 124 9.9e−08 1 CFI_MAIZE (Q08704) Chalcone--flavonone isomerase (EC 5.5 . . . 138 1.1e−07 1 Q84T92_ORYSA (Q84T92) Chalcone isomerase - Oryza sativa (. . . 138 1.2e−07 1 CFI_VITVI (P51117) Chalcone--flavonone isomerase (EC 5.5 . . . 137 1.7e−07 1 Q42926_MALSP (Q42926) Chalcone isomerase (EC 5.5.1.6) (Fr . . . 120 2.8e−07 1 CFI_CALCH (Q42663) Chalcone--flavonone isomerase (EC 5.5 . . . 135 3.1e−07 1 Q9FLC7_ARATH (Q9FLC7) Similarity to chalcone-flavonone is . . . 132 3.3e−07 1 Q8VZW3_ARATH (Q8VZW3) Hypothetical protein At5g05270 (Con . . . 132 3.8e−07 1 Q66VY9_ALLCE (Q66VY9) Chalcone isomerase - Allium cepa (O . . . 133 4.4e−07 1 CFIA_PETHY (P11650) Chalcone--flavonone isomerase A (EC 5 . . . 134 4.4e−07 1 Q66VY8_ALLCE (Q66VY8) Chalcone isomerase - Allium cepa (O . . . 132 5.9e−07 1 Q8S3X1_ORYSA (Q8S3X1) Chalcone isomerase (EC 5.5.1.6) - O . . . 132 6.8e−07 1 CFIB_PETHY (P11651) Chalcone--flavonone isomerase B (EC 5 . . . 131 6.8e−07 1 CFI_ELAUM (O65333) Chalcone--flavonone isomerase (EC 5.5 . . . 133 7.3e−07 1 CFI_PUELO (Q43056) Chalcone--flavonone isomerase (EC 5.5 . . . 130 9.9e−07 1 Q38HM0_AQUFO (Q38HM0) Putative chalcone isomerase (Fragme . . . 114 1.3e−06 1 Q8H0G2_LOTJA (Q8H0G2) Putative chalcone isomerase - Lotus . . . 128 1.8e−06 1 Q53B71_SOYBN (Q53B71) Chalcone isomerase 4B (Fragment) - . . . 112 2.1e−06 1 Q9M5B3_PETHY (Q9M5B3) Chalcone isomerase A (EC 5.5.1.6) - . . . 128 2.4e−06 1 CHI_ARALP (Q9LKC3) Chalcone--flavonone isomerase (EC 5.5 . . . 127 3.2e−06 1 CFI_ARATH (P41088) Chalcone--flavonone isomerase (EC 5.5 . . . 126 4.4e−06 1 CFI2_MEDSA (P28013) Chalcone--flavonone isomerase 2 (EC 5 . . . 122 5.1e−06 1 Q6QHK0_ALLCE (Q6QHK0) Chalcone isomerase - Allium cepa (O . . . 123 7.6e−06 1 CFI1_MEDSA (P28012) Chalcone--flavonone isomerase 1 (EC 5 . . . 122 9.3e−06 1 Q8GXU6_ARATH (Q8GXU6) Hypothetical protein At2g26310 - Ar . . . 119 2.0e−05 1 Q9FKW3_ARATH (Q9FKW3) Chalcone isomerase-like protein - A . . . 119 2.2e−05 1 Q8H0F6_LOTJA (Q8H0F6) Chalcone isomerase - Lotus japonicus 119 2.2e−05 1 Q84RQ2_LOTJA (Q84RQ2) Chalcone isomerase (EC 5.5.1.6) - L . . . 118 2.4e−05 1 Q93XE6_SOYBN (Q93XE6) Chalcone isomerase 1A (EC 5.5.1.6) . . . 117 3.5e−05 1 Q84RK3_ARATH (Q84RK3) Hypothetical protein At2g26310/T1D1 . . . 119 3.8e−05 1 Q58G09_ARATH (Q58G09) Hypothetical protein - Arabidopsis . . . 119 8.4e−05 1 CFI_RAPSA (O22651) Chalcone--flavonone isomerase (EC 5.5 . . . 114 0.00012 1 CFI_SOYBN (O81980) Chalcone--flavonone isomerase (EC 5.5 . . . 104 0.00051 1 Q84RK2_ARATH (Q84RK2) Hypothetical protein At2g26310/T1D1 . . . 111 0.00068 1 CFI_PHAVU (P14298) Chalcone--flavonone isomerase (EC 5.5 . . . 104 0.0013 1 Q9SXS9_CICAR (Q9SXS9) Chalcone isomerase (Fragment) - Cic . . . 93 0.0037 1 Q84S97_RAPSA (Q84S97) Chalcone flavanone isomerase (Fragm . . . 94 0.0089 1 CFI_PEA (P41089) Chalcone--flavonone isomerase (EC 5.5.1 . . . 96 0.011 1 Q6K7H0_ORYSA (Q6K7H0) Hypothetical protein OJ1293_A01.5 - . . . 100 0.013 1 Q3HNP7_ASTME (Q3HNP7) Chalcone isomerase (Fragment) - Ast . . . 89 0.013 1 Q69SP9_ORYSA (Q69SP9) Hypothetical protein OSJNBa0016O19 . . . 92 0.100 1 Q94IU6_FRAVE (Q94IU6) Chalcone isomerase (Fragment) - Fra . . . 69 0.11 1 Q8LGS3_ROSHC (Q8LGS3) Chalcone isomerase (Fragment) - Ros . . . 81 0.14 1 Q8RVM9_MALDO (Q8RVM9) Chalcone isomerase (Fragment) - Mal . . . 77 0.20 1 Q4AEC1_WHEAT (Q4AEC1) Chalcone isomerase (Fragment) - Tri . . . 72 0.80 1 Q94KX0_BRANA (Q94KX0) Chalcone flavonone synthase (Fragme . . . 58 0.84 1 Q94KX4_BRANA (Q94KX4) Chalcone flavonone synthase (Fragme . . . 57 0.90 1 Q94KX1_BRAOL (Q94KX1) Chalcone flavonone synthase (Fragme . . . 56 0.95 1 Q76K33_PRUPE (Q76K33) Chalcone isomerase (Fragment) - Pru . . . 55 0.98 1 Q3E948_ARATH (Q3E948) Protein At5g25750 - Arabidopsis tha . . . 55 0.98 1 Q7G6C8_ORYSA (Q7G6C8) Hypothetical protein OSJNAb0022I16 . . . 72 0.9998 1

Similarly, At396 was searched against UNIPROT as described, using a query sequence length of 396 letters, in the database: /home/patlibs/Uniprot Plant Proteins. Table 5 provides results of the search. Sequence alignments between At396 and any of the sequences below can be produced by WU-BLAST 2.0, e.g., set to default parameters and viewed with publicly available sequence alignment tools such as those provided by TAIR (similar searches can be run directly in UniProt or other available databases). Sequences below are obtained by providing the indicated sequence accession number (in parentheses) to the UniProt database (e.g., on the world wide web at pir(dot)uniprot(dot)org.

TABLE 5 Blast Results for At396 Smallest Sum High Probability Sequences prfoducing High-scoring Segment Pairs: Score P(N) N Q58G09_ARATH (Q58G09) Hypothetical protein - Arabidopsis . . . 1943  5.6e−201 1 Q84RK2_ARATH (Q84RK2) Hypothetical protein At2g26310/T1D1 . . . 1935  3.9e−200 1 Q84RK3_ARATH (Q84RK3) Hypothetical protein At2g26310/T1D1 . . . 1311  5.2e−134 1 Q8GXU6_ARATH (Q8GXU6) Hypothetical protein At2g26310 - Ar . . . 1002  2.9e−101 1 Q6K7H0_ORYSA (Q6K7H0) Hypothetical protein OJ1293_A01.5 - . . . 700 2.9e−69 1 Q69SP9_ORYSA (Q69SP9) Hypothetical protein OSJNBa0016O19 . . . 639 8.5e−63 1 Q9M1X2_ARATH (Q9M1X2) Hypothetical protein F16M2_20 (Hypo . . . 283 4.5e−25 1 O64841_ARATH (O64841) Hypothetical protein At2g26310 - Ar . . . 221 6.1e−23 2 Q6V7U9_LYCES (Q6V7U9) Putative chalcone isomerase - Lycop . . . 230 3.5e−19 1 Q53B73_SOYBN (Q53B73) Putative chalcone isomerase 3 - Gly . . . 133 2.1e−06 1 Q8LFP0_ARATH (Q8LFP0) Chalcone isomerase, putative - Arab . . . 119 8.6e−05 1 Q6YTV0_ORYSA (Q6YTV0) Hypothetical protein OJ1121_A05.15 . . . 99 0.00010 1 Q9C8L2_ARATH (Q9C8L2) Chalcone isomerase, putative; 94270 . . . 112 0.00054 1 Q5M9R4_TOBAC (Q5M9R4) Hypothetical protein orf134b - Nico . . . 71 0.98 1 Q4G3B6_EMIHU (Q4G3B6) Hypothetical chloroplast RF40 - Emi . . . 54 0.9995 1 Q53B70_SOYBN (Q53B70) Chalcone isomerase 1B2 (EC 5.5.1.6) . . . 73 0.9998 1 Q84T92_ORYSA (Q84T92) Chalcone isomerase - Oryza sativa (. . . 73 0.9999 1

While the foregoing invention has been described in some detail for purposes of clarity and understanding, it will be clear to one skilled in the art from a reading of this disclosure that various changes in form and detail can be made without departing from the true scope of the invention. For example, all the techniques and apparatus described above can be used in various combinations. All publications, patents, patent applications, and/or other documents cited in this application are incorporated by reference in their entirety for all purposes to the same extent as if each individual publication, patent, patent application, and/or other document were individually indicated to be incorporated by reference for all purposes. 

1. A recombinant cell that expresses a heterologous chalcone isomerase like fatty acid binding protein gene, which gene encodes a chalcone isomerase like fatty acid binding protein that binds to a fatty acid in the cell.
 2. The recombinant cell of claim 1, wherein the gene encodes At287 (At1g53520), At279 (At3g63170), At396 (At2g26310) or a homolog thereof.
 3. The recombinant cell of claim 2, wherein the gene encodes one or more protein identified in Tables 3-5.
 4. The recombinant cell of claim 1, wherein the gene encodes a chalcone isomerase like fatty acid binding protein that is at least 25% identical to At287, At279, or At396 and that encodes a conserved Arg amino acid residue in a position corresponding to Arg 103 of At279 or Arg 114 of At287, and that encodes a conserved Tyr residue in a position corresponding to Tyr 116 of At279 or Tyr 126 of At287, which conserved Arg and conserved Tyr residues participate in sequestering a carboxylic acid moiety on the fatty acid when the fatty acid is bound to the protein.
 5. The recombinant cell of claim 4, wherein the gene is at least 60% identical to At287, At279, or At396.
 6. The recombinant cell of claim 1, wherein the gene is more highly expressed than a corresponding native chalcone isomerase like fatty acid binding protein gene of the cell, thereby increasing lipid content of the recombinant cell as compared to a corresponding cell that does not express the gene.
 7. The recombinant cell of claim 1, wherein the protein regulates transport of the fatty acid from an inner thylakoid membrane of the cell to an outer membrane of a plastid of the cell.
 8. The recombinant cell of claim 1, wherein the cell is a plant cell.
 9. The recombinant cell of claim 1, wherein the cell is a cell of a recombinant plant.
 10. The recombinant cell of claim 9, wherein the plant is a member of a family selected from: Graminae, Leguminosae, Compositae and Rosaciae, or wherein the plant is a member of a genus selected from Agrostis, Allium, Antirrhinum, Apium, Arachis, Asparagus, Atropa, Avena, Bambusa, Brassica, Bromus, Browaalia, Camellia, Cannabis, Capsicum, Cicer, Chenopodium, Chichorium, Citrus, Coffea, Coix, Cucumis, Curcubita, Cynodon, Dactylis, Datura, Daucus, Digitalis, Dioscorea, Elaeis, Eleusine, Festuca, Fragaria, Geranium, Glycine, Helianthus, Heterocallis, Hevea, Hordeum, Hyoscyamus, Ipomoea, Lactuca, Lens, Lilium, Linum, Lolium, Lotus, Lycopersicon, Majorana, Malus, Mangifera, Manihot, Medicago, Nemesia, Nicotiana, Onobrychis, Oryza, Panicum, Pelargonium, Pennisetum, Petunia, Pisum, Phaseolus, Phleum, Poa, Prunus, Ranunculus, Raphanus, Ribes, Ricinus, Rubus, Saccharum, Salpiglossis, Secale, Senecio, Setaria, Sinapis, Solanum, Sorghum, Stenotaphrum, Theobroma, Trifolium, Trigonella, Triticum, Vicia, Vigna, Vitis, Zea, the Olyreae, and the Pharoideae.
 11. The recombinant cell of claim 9, wherein the plant is a Zea mays, soybean, cotton, Brassica naupus, Brassica juncea, tobacco, sunflower, safflower, rapeseed, canola, olive or Arabidopsis thalina plant.
 12. The recombinant cell of claim 1, wherein the fatty acid is oleic acid, lauric acid, myristic acid, palmitic acid or steric acid.
 13. The recombinant cell of claim 1, wherein the fatty acid is saturated.
 14. The recombinant cell of claim 1, wherein the fatty acid is unsaturated.
 15. A recombinant cell that expresses a heterologous regulator of a chalcone isomerase like fatty acid binding protein gene.
 16. The recombinant cell of claim 15, wherein the regulator is selected from the group consisting of: a transcription factor that regulates expression of the gene, an anti-sense nucleic acid that inhibits transcription or translation of an mRNA encoded by the gene, an siRNA that inhibits translation of an mRNA encoded by the gene, and an miRNA that inhibits translation of an mRNA encoded by the gene.
 17. The recombinant cell of claim 15, wherein the regulator increases production of a chalcone isomerase like fatty acid binding protein in the cell, thereby increasing lipid content of the cell.
 18. The recombinant cell of claim 15, wherein the regulator decreases production of a chalcone isomerase like fatty acid binding protein in the cell, thereby decreasing lipid content of the cell.
 19. An expression vector that encodes a chalcone isomerase like fatty acid binding protein.
 20. The expression vector of claim 19, wherein the gene encodes At287, At279, At396 or a homolog thereof.
 21. The expression vector of claim 19, wherein the expression vector is expressible in a plant, bacteria, fungi or mammalian cell.
 22. An isolated chalcone isomerase like fatty acid binding protein.
 23. The isolated protein of claim 22, wherein the protein is At287, At279, or a homolog thereof.
 24. A crystal comprising a chalcone isomerase like fatty acid binding protein.
 25. The crystal of claim 24, wherein the crystal comprises At287, At279, At396 or a homolog thereof.
 26. The crystal of claim 24, wherein the crystal comprises a fatty acid bound to the protein.
 27. A method of making a recombinant cell, the method comprising: introducing a recombinant gene into a cell, which recombinant gene encodes a recombinant chalcone isomerase like fatty acid binding protein; and, expressing the recombinant gene in the resulting recombinant cell.
 28. The method of claim 27, wherein the gene encodes At287, At279, At396 or a homolog thereof.
 29. The method of claim 27, wherein the cell is a plant cell.
 30. The method of claim 27, wherein the recombinant chalcone isomerase like fatty acid binding protein is more highly expressed than a native chalcone isomerase like fatty acid binding protein homolog.
 31. The method of claim 27, wherein expression of the recombinant chalcone isomerase like fatty acid binding protein increases lipid content of the cell.
 32. A recombinant plant cell made by the method of claim
 29. 33. A method of modulating lipid content of a cell, the method comprising: expressing a recombinant chalcone isomerase like fatty acid protein gene in the cell, or expressing a heterologous modulator of a chalcone isomerase like fatty acid protein gene in the cell; wherein expression of the recombinant gene or heterologous modulator modulates lipid content of the cell.
 34. The method of claim 33, wherein expression of the recombinant chalcone isomerase like fatty acid protein gene increases lipid content of the cell.
 35. The method of claim 33, wherein expression of the modulator increases lipid content of the cell.
 36. The method of claim 33, wherein expression of the modulator decreases lipid content of the cell.
 37. A cell made by the method of claim
 33. 38. A method of selecting a plant for lipid content, the method comprising: identifying a polymorphism in a plant population that correlates with a phenotype encoded by a chalcone isomerase like fatty acid binding protein gene; and, performing marker assisted selection of the population to select a plant in the population for the polymorphism.
 39. The recombinant cell of claim 38, wherein the gene is the same as or homologous to a gene that encodes At287, At279, or At396.
 40. A plant produced by the method of claim
 38. 41. A method of modifying a chalcone isomerase like fatty acid binding protein, the method comprising: accessing an information set derived from a crystal structure of the protein or homolog thereof, and, based on information in the information set, predicting whether making a change to the structure of the protein will increase or decrease binding to a fatty acid binding protein ligand; and, modifying the protein based upon on said predicting.
 42. The method of claim 41, wherein the information set comprises crystal structure coordinate information in FIGS. 5-6.
 43. A system comprising an information storage module comprising an information set derived from a crystal structure of a chalcone isomerase like fatty acid binding protein. 